May 26, 197B
SUPPLEMENT NO. 7
TO THE
SAFETY EVALUATION REPORT
BY THE
OFFICE OF NUCLEAR REACTOR REGULATION
U. S. NUCLEAR REGULATORY COMMISSION
IN THE MATTER OF
PACIFIC GAS AND ELECTRIC COMPANY
DIABLO CANYON NUCLEAR POWER STATION, UNITS 1 AND 2
DOCKET NOS. 50-275 AND 50-323
TABLE OF CONTENTS
PAGE
1.0 INTRODUCTION ............................................................. 1-1
2.0 SITE CHARACTERISTICS ..................................................... 2-1
2.2 Nearby Industrial, Transportation and Military Facilities ........... 2-1
2.3 Meteorology ......................................................... 2-1
2.3.3 Onsite Meteorological Measurements Program ................... 2-1
2.4 Hydrology ........................................................... 2-2
2.5 Geology, Seismology and Foundation Engineering ...................... 2-3
2.5.2 Seismology ................................................... 2-3
2.5.3 Slope Stability ............................................... 2-6
3.0 DESIGN CRITERIA - STRUCTURES COMPONENTS, EQUIPMENT AND SYSTEMS ........... 3-1
3.2 Classification of Structures, Components and Systems ................ 3-1
3.2.1 Seismic Classification ....................................... 3-1
3.3 Wind and Tornado Design Criteria .................................... 3-5
3.5 Missile Protection Criteria ......................................... 3-9
3.6 Protection Against the Dynamic Effects Associated with the
-Postulated Rupture of Piping ........................................ 3-12
3.7 Seismic Design ...................................................... 3-13
3.8 Design of Category I Structures ..................................... 3-15
3.8.5 Seismic Reevaluation ..... : ................................... 3-15
3.8.5.1 Summary of Staff Review .............................. 3-15
3.8.5.2 Ground Response Spectra ............................... 3-17
3.8.5.3 General Methods of Analysis .......................... .3-19
3.8.5.4 Structural Analysis .................................. 3-24
3.8.5.4.1 Containment Shell ........................ 3-24
3.8.5.4.2 Containment Interior Structures .......... 3-27
3.8.5.4.3 Auxiliary Building ....................... 3-30
3.8.5.4.4 Intake Structure ......................... 3-33
3.8.5.4.5 Turbine Building ......................... 3-36
i
p
TABLE OF CONTENTS (Continued)
PAGE
3.8.5.4.6 Buried Pipes ............................. 3-41
3.8.5.4.7 Outdoor Tanks ............................ 3-42
3.8.5.4.8 Cranes ................................... 3-44
3.8.5.4.9 Conclusions .............................. 3-45
3.9 Mechanical Systems and Components ................................... 3-47
3.9.3 Seismic Reevaluation .................... .................... 3-47
3.9.3.1 Summary of Staff Review ................................ 3-47
3.9.3.2 General Methods of Analysis ........................... 3-48
3.9.3.2.1 Description of Methods ......................... 3-48
3.9.3.2.2 Evaluation of Methods ......................... 3-50
3.9.3.3 Floor Response Spectra ................................ 3-51
3.9.3.4 Piping System Analysis ................................ 3-52
3.9.3.4.1 Response Combinations .......................... 3-52
3.9.3.4.2 Reactor Coolant System Main Loops .............. 3-54
3.9.3.4.3 Reactor Coolant System Branch Piping ........... 3-57
3.9.3.4.4 Other Piping ................................... 3-58
3.8.3.4.5 Simplified Analyses ............................ 3-60
3.8.3.4.6 Conclusions ...................... ............. 3-61
3.9.3.5 Seismic Category I Piping Boundaries .................. 3-62
3.9.3.6 Piping Snubber Study .................................. 3-63
3.9.3.7 Seismic Qualification of Mechanical Components ........ 3-65
3.9.3.8 Design Interfaces..................................... 3-68
3.9.3.9 Summary of Outstanding Items .......................... 3-69
3.10 Seismic Qualification of Category I Instrumentation and Electrical
Equipment ........................................................... 3-71
3.10.1 Introduction .............................................. 3-71
3.10.2 Criteria .................................................. 3-71
3.10.3 Balance-of-Plant Equipment ................................ 3-73
3.10.4 Nuclear Steam Supply System Equipment ..................... 3-74
ii
TABLE OF CONTENTS (Continued)
PAGE
3.10.5 Documentation ............................................. 3-75
3.10.6 Summary of Outstanding Items .............................. 3-75
5.0 REACTOR COCLANT SYSTEM ................................................... 5-1
5.2 Integrity of Reactor Coolant Pressure Boundary ...................... 5-1
5.2.4 Fracture Toughness ........................................... 5-1
6.0 ENGINEERED SAFETY FEATURES ............................................... 6-1
6.2 Containment Systems ................................................. 6-1
6.2.1 Containment Functional Design ................................ 6-1
6.2.3 Containment Air Purification and Cleanup Systems ............. 6-5
6.3 Emergency Core Cooling System (ECCS) ................................ 6-5
7.0 INSTRUMENTATION AND CONTROLS ............................................. 7-1
7.2 Reactor Trip System ................................................. 7-1
7.4 Systems Required for Safe Shutdown .................................. 7-1
7.8 Environmental and Seismic Qualification ............................. 7-2
8.0 ELECTRIC POWER ........................................................... 8-1
8.3 Onsite Power ......................................................... 8-1
9.0 AUXILIARY SYSTEMS ........................................................ 9-1
9.5 Air Conditioning, Heating and Ventilation Systems ................... 9-1
9.5.5 Diesel Generator Compartments ................................ 9-1
9.6 Other Auxiliary Systems ............................................. 9-1
9.6.1 Fire Protection System ....................................... 9-1
iii
TABLE OF CONTENTS (Continued)
PAGE
10.0 STEAM AND POWER CONVERSION SYSTEMS ...................................... 10-1
10.4 Other Features ...................................................... 10-1
10.5 Auxiliary Feedwater System .......................................... 10-2
13.0 CONDUCT OF OPERATIONS .................................................... 13-1
13.3 Emergency Planning .................................................. 13-1
13.6 Industrial Security ................................................. 13-2
18.0 REVIEW BY THE ADVISORY COMMITTEE ON REACTOR SAFEGUARDS (ACRS) ............ 18-1
20.0 FINANCIAL QUALIFICATIONS ................................................. 20-1
22.0 CONCLUSIONS .............................................................. 22-1
iv
TABLE OF CONTENTS (Continued)
PAGE
APPENDICES
APPENDIX A CONTINUATION OF CHRONOLOGY OF THE REGULATORY REVIEW ............ A-i
APPENDIX B CONTINUATION OF DISCUSSION, ADVISORY COMMITTEE ON
REACTOR SAFEGUARDS GENERIC ITEMS ............................... B-1
APPENDIX C REPORT BY THE ADVISORY COMMITTEE ON REACTOR SAFEGUARDS
DATED AUGUST 19, 1977 .......................................... C-i
APPENDIX D BIBLIOGRAPHY ................................................... D-i
FIGURES
FIGURE 3-1 Schematic Layout of Diesel Generator Rooms and Cable
Spreading Rooms and Switchgear Rooms in the Turbine
Building ....................................................... 3-77
FIGURE 3-2 Layout of Vulnerable Main Steam Relief Valves and Cable
Trays Outside of Plant ......................................... 3-78
FIGURE 3-3 Diablo Canyon Seismic Reevaluation, Comparison of
Hosgri Event Spectra .......................................... 3-79
FIGURE 3-4 Diablo Canyon Seismic Reevaluation, Comparison of
Hosgri Event Spectra ......................................... 3-80
FIGURE 3-5 Diablo Canyon Seismic Reevaluation, Comparison of
Hosgri Event Spectra ......................................... 3-81
FIGURE 3-6 Diablo Canyon Seismic Reevaluation, Comparison of
Hosgri Event Spectra ......................................... 3-82
v
1.0 INTRODUCTION
General
The Commission's Safety Evaluation Report in the matter of Pacific Gas and
Electric Company's application for operating licenses for the Diablo Canyon
Nuclear Power Station, Units 1 and 2, was issued on October 16, 1974. In the
Safety Evaluation Report it was stated that supplemental reports would be issued
to update the Safety Evaluation Report in those areas where the staff's evaluation
had not been completed. Supplement Nos. 1, 2, 3, 4, 5 and 6 to the Safety
Evaluation Report, issued on January 31, 1975, May 9, 1975, September 18, 1975,
May 11, 1976, September 10, 1976, and July 14, 1977, respectively, documented the
resolution of certain outstanding items and summarized the status of the remaining
outstanding items.
In this supplement we further update the Safety Evaluation Report and its previous
supplements by providing (1) our evaluation of certain matters that were not
resolved when Supplement No. 6 was issued, (2) our evaluation of new issues that
have arisen since Supplement No. 6 was issued, and (3) a discussion of the items
identified by the Advisory Committee on Reactor Safeguards in its report of
August 19, 1977. Each of the following sections of this supplement is numbered
the same as the corresponding sections of the Safety Evaluation Report and
previous supplements that are being updated, except for Sections 3.8.5 and 3.9.3
which are new section numbers created here to discuss the seismic reevaluation.
A summary of the remaining outstanding issues, which will be addressed in future
supplements to the Safety Evaluation Report, is presented in Section 22.0 of this
supplement.
The principal outstanding issue in our review of this operating license
application has been the earthquake capabilities of the Hosgri fault and its
impact on seismic design considerations for this plant. As a result of this
matter, the applicant has performed a reevaluation of the plant's seismic
capabilities to determine what modifications are necessary in order to demonstrate
that the plant can withstand a more severe earthquake than was considered in the
original design.
Our review of the applicant's seismic reevaluation has not yet been completed, and
a number of issues remain to be resolved. However, we have completed a
substantial part of the review which has been more comprehensive than normal. The
main purpose ofthis supplement is to describe the status of this review and the
status. of the items that remain to be resolved.
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Appendix A to this supplement is a continuation of the chronology of the principal
events involved in the Commission staff's radiological safety review. Appendix B
is a continuation of our discussion of the Advisory Committee on Reactor
Safeguards generic items. Appendix C is a copy of a report by the Advisory
Committee on Reactor Safeguards concerning nonseismic aspects of the Diablo Canyon
Plant. Appendix D is a bibliography.
Status of Review
As indicated in Appendix A to this supplement, the applicant has submitted amend-
ments to the operating license application through Amendment 61 dated March 28, 1978.
In order to expedite the review process, the applicant has supplemented these
amendments with numerous letters. The information provided in these letters that
we have relied on in our review will, in the future, be incorporated into the
operating license application.
Although in a few, instances we have reviewed more recent material, as a general
rule our review of amendments has progressed through Amendment 57, dated
January 23, 1978, and our review of letters submitted by the applicant has
progressed through the applicant's letter of March 27, 1978. Accordingly, our
-evaluations as described in this supplement are based primarily upon material
through these dates. Our evaluation of the more recent submittals will be
described in a future supplement to the Safety Evaluation Report.
Seismic Reevaluation - Background
The construction permits for Units I and 2 of the Diablo Canyon Nuclear Power
Plant were issued by the Atomic Energy Commission in 1968 and 1970, respectively.
The plant was originally designed and built to meet the seismic design criteria
that were approved during the construction permit reviews. These original
criteria were discussed in Section 2.5 of Supplement No. 1 to the Safety
Evaluation Report. They included an operating basis earthquake at O.2g horizontal
acceleration and a safe shutdown earthquake at O.4g horizontal acceleration.
Our operating license review began in 1973. As part of this review we requested
additional information from PG&E about the Hosgri fault, which had come to light
in 1971. PG&E as well as our consultant, the U.S. Geological Survey, conducted
further investigations of the fault.
While we were still evaluating the earthquake potential of the Hosgri fault, we
completed our evaluation of the plant's original seismic design. Our evaluation
of this original seismic design was presented in Section 3.0 of the Safety Evalu-
ation Report in October 1974. We found the design acceptable in relation to the
original criteria except for the seismic qualification of electrical equipment,
which was listed as an open item.
1-2
In November 1974, based on preliminary estimates of the Hosgri fault's earthquake
potentiaj, we requested a reevaluation of the plant's seismic capabilities based
on two specific earthquake spectra normalized to O.5g horizontal ground accelera-
tion. PG&E responded in December 1974, and this information was later reviewed by
the staff. We also later conducted a one week audit of PG&E's original design and
the reevaluation performed for 0.5g. The reevaluation at 0.5g used a simplified
approach. Floor response spectra for the new conditions were developed and were
compared with the original floor response spectra. We did not formally complete
this review and publish our conclusions and their bases in a Safety Evaluation
Report. However, our review was completed for all practical purposes and we
considered that the simplified approach had demonstrated that the plant's original
design was adequate for the 0.5g conditions, subject to satisfactory resolution of
the outstanding issues concerning seismic qualification of electrical equipment.
This was documented in our response of July 8, 1976 to discovery requests from the
San Luis Obispo Mothers for Peace, et. al., intervenors in the Diablo Canyon
proceedings.
While our review of the seismic design capability for 0.5g was in progress, the
question became moot. The staff received an evaluation from the U.S. Geological
Survey (USGS) in January 1975 indicating that, in light of then available informa-
tion about the Hosgri fault, the seismic hazard characterized by 0.5g acceleration
would not be adequate. This evaluation of the Hosgri fault was described in
Supplement No. 1 to the Safety Evaluation Report and our review of the Hosgri
fault's earthquake potential continued.
In April 1976 we completed our review of the Hosgri fault's earthquake potential.
As a result of our evaluation, we once again requested that the applicant
reevaluate the plant's seismic design capabilities. The USGS recommended assuming
a magnitude 7.5 earthquake on the Hosgri fault and provided instrumental ground
motion values to be associated with such an event. As the USGS also recommended,
we developed effective ground motion values to be used in the reanalysis. These
effective values were based on the recommendation of our consultant, Dr. N. M. Newmark.
The ground response spectra involved in the reevaluation are anchored at 0.75g
horizontal acceleration, prior to any reduction of the high frequency portion to
account for building size effects. Further discussions of our evaluation of the
Hosgri fault and the criteria to be used in the seismic reevaluation at 0.75g are
presented in Sections 2.5 and 3.7 of Supplements 4 and 5 to the Safety Evaluation
Report.
PG&E did not agree with our conclusions regarding the Hosgri fault, maintaining
that the plant's original design was adequate with respect to the Hosgri fault.
Nevertheless, PG&E has performed the reevaluation and is proceeding to install the
appropriate plant modifications which are fairly extensive.
1-3
Seismic Reevaluation - Current Status
PG&E has described the Hosgri reevaluation in a separate report entitled, "Seismic
Evaluation for Postulated 7.5M Hosgri Earthquake." This extensive six-volume
report on the reanalysis was submitted as Amendment 50 to the operating license
application and has subsequently been revised and expanded by Amendments 53, 56,
59 and 60. As discussed above, these amendments have been supplemented by numerous
letters from the applicant which will be incorporated into the application in the
future.
In addition to reviewing the documents submitted by the applicant we have held
numerous meetings with the applicant in order to determine in further detail how
the criteria and procedures for the seismic reevaluation were carried out. These
meetings have been called seismic design criteria implementation review meetings
or, more simply, audits. In connection with these meetings, PG&E has informally
provided voluminous detailed technical information, such as calculations, specifi-
cations, drawings and data sheets. Much of this information was reviewed during
meetings in the applicant's offices and left there, no copies being kept by the
staff. Other information of a similar nature was informally provided for later
review. As is our usual practice for this type of information we have placed it
in our filesand made it available in the public document rooms. However, most of
this information will not be incorporated into the application.
The following list indicates the secti.ons in this supplement where the principal
aspects of the seismic reevaluation.are discussed:
Section 1.0 Introduction
Section 2.4 Tsunami protection
Section 2.5.2 Operating basis earthquake
Section 2.5.3 Slope stability
Section 3.2.1 Items to be qualified for Hosgri event
Section 3.7 General criteria
Section 3.8 Structures, tanks and buried piping
Section 3.9 Mechanical systems and equipment. Includes reactor coolant
system except fuel.
Section 3.10 Seismic qualification of electrical equipment
Section 6.2.1 Subcompartment pressure calculations for asymmetric pressure
loads.
Section 6.3 Reactor fuel, emergency core cooling performance.
Seismic Reevaluation - Modifications
The applicant has begun installing the plant modifications that were indicated to
be necessary by the applicant's seismic reevaluation (including requalification of
some equipment by retesting). Our discussions with the applicant's personnel
1-4
indicate that the applicant intends to complete such seismic modifications for
Unit I and Unit 2, respectively, prior to operation of the units. Our review is
proceeding on the basis that the plant must be modified as necessary to
demonstrate that it can safely withstand the postulated Hosgri earthquake.
Interim License Request
In a motion before the Atomic Safety and Licensing Board dated August 25, 1977 the
applicant requested an interim operating license for Unit 1. The motion requested
authorization to operate Unit 1 prior to completion of the Commission's review and
issuance of a decision by the Board on the normal or full-term operating license
application. At the time this would have meant operation prior to completing the
seismic modifications. The request was based on probabilistic risk assessments
and other considerations.
At the present time we are not reviewing the interim license request. We did
review it intensively for some time and then, in December 1977, we suspended our
interim license review (except for probability studies) in order to concentrate
our efforts on the normal or full-term license review. This action is discussed
more fully in a letter to the applicant dated January 23, 1978 and in our
summaries of meetings with the applicant on November 3 and December 15, 1977. In
a letter to the Board dated February 8, 1978 the applicant indicated that it may
wish to reactivate the interim license request if the full-term license review
should later be delayed for some unforseen reason.
Our review of the probabilistic seismic risk assessments is continuing. These
assessments are extensive, dealing with both the probabilities of earthquakes
occurring and the probabilities of causing failures in the plant. They provide
useful background information regarding several aspects of the seismic design
process.
We have used the seismic probability studies for background information in limited
cases in reaching conclusions about the normal or full-term license review. To
the extent this was done, our evaluation is provided in this supplement. (See
Sections 2.5.4 and 3.2.1 of this supplement.) Our general evaluation of the
probabilistic seismic risk assessments will be provided in a separate report - not
a supplement to the Safety Evaluation Report.
1-5
2.0 SITE CHARACTERISTICS
2.2 Nearby Industrial, Transportation and Military Facilities
In Section 2.2 of the Safety Evaluation Report, we concluded that, because of the
absence of industrial, transportation or military facilities in the area of the
site, safe operation of the plant would not be adversely affected.
Recently, during the first half of 1978, the State of California has been
considering potential sites for a terminal to receive imported liquified natural
gas. One of the sites under consideration is at Rattlesnake Canyon, about four
miles south of the Diablo Canyon Nuclear Power Plant.
We do not consider this to be an outstanding review issue at the present time
since the planning for the terminal has not progressed to the stage where
construction of the facility close to the Diablo Canyon plant is a likely
possibility. If the planning does progress to that point, a specific safety
evaluation of the potential impact of the terminal on the Diablo Canyon Nuclear
Power Plant will be necessary.
2.3 Meteorology
2.3.3 Onsite Meteorological Measurements Program
In Section 2.3.3 of Supplement No. 2 to the Safety Evaluation Report, we found the
applicant's program for control room monitoring of meteorological parameters
acceptable.
In Amendment 57 to the Final Safety Analysis Report, the applicant proposed revi-
sions to the program for display of meteorological parameters in the control room.
After reviewing the proposal, we informally requested clarification of some items,
including the specific display provided for the operator. This information was
submitted by the applicant in Amendment 61 to the Final Safety Analysis Report.
We have not yet completed our review of this information. When our evaluation is
completed, we will report the results in a future supplement to the Safety
Evaluation Report.
2-1
2.4 Hydrology
Our evaluation of near-shore generated tsunamis was presented in Section 2.4 of
Supplement No. 5 to the Safety Evaluation Report where we concluded that the
tsunami protection was acceptable. As discussed in Section 2.5.3 of this supple-
ment, we have refined our estimate of the amount of breakwater slumping that would
be caused by the Hosgri event. This revision yielded an improved safety margin
from the standpoint of tsunami protection and, accordingly, our conclusion remains
unchanged.
We consider this matter resolved.
As discussed in Section 3.2.1 of this supplement, the applicant is qualifying the
raw water storage reservoirs as an extended source of auxiliary feedwater that
would be available to conduct a safe shutdown following the Hosgri event. As part
of our review we will require analysis of the potential for seiches causing a
significant loss of water from the reservoir. We will provide our evaluation of
this matter in a future supplement to the Safety Evaluation Report.
2-2
2.5 Geology, Seismology and Foundation Engineering
2.5.2 Seismology
In Section 2.5.2 of the Safety Evaluation Report, we discussed the original
seismic design criteria for the plant. In Sections 2.5 and 3.7 of Supplements 4
and 5 to the Safety Evaluation Report, we described the criteria that we had
approved for use in the seismic reevaluation. These criteria consisted primarily
of the ground response spectra to be used.
Terminology
In order to avoid possible confusion about the names of the'earthquake design
bases we will use the following terminology:
(1) Design earthquake
(2) Double design earthquake
(3) Hosgri event
The status of these three events is as follows:
(1) Design earthquake (0.2g)
This was originally the equivalent of the event that was later formally
defined as the Operating Basis Earthquake in Appendix A to 10 CFR Part 100,
"Seismic and Geologic Siting Criteria for Nuclear Power Plants." The
applicant calls it the design earthquake following the original terminology.
In previous supplements to the Safety Evaluation Report, we have called it
the operating basis earthquake following the terminology of Appendix A to
10 CFR Part 100.
As discussed below, we have concluded that the applicant has justified that
this event still satisfies the requirements for an operating basis earthquake
at this site.
(2) Double design earthquake (O.4g)
This was originally the equivalent of the event that was later formally
defined as the safe shutdown earthquake in Appendix A to 10 CFR Part 100.
The applicant calls it the double design earthquake following the original
terminology. In previous supplements to the Safety Evaluation Report, we
have called it the safe shutdown earthquake following the terminology of
Appendix A to 10 CFR Part 100.
2-3
The applicant still considers this to be the appropriate safe shutdown earth-
quake for this site as defined in Appendix A to 10 CFR Part 100. The appli-
cant's position was most recently stated in a letter to the NRC staff dated
April 11, 1978.
(3) Hosgri event (0.75g)
This is the basis that we have approved for use in the seismic reevaluation.
The applicant calls this the postulated 7.5M Hosgri earthquake (event) or the
postulated Hosgri earthquake (event). In previous supplements to the Safety
Evaluation Report, we have called it a magnitude 7.5 earthquake on the Hosgri
fault with ground response spectra normalized to an effective value of 0.75g
at the site.
Contrary to the applicant's position, we consider this to be the safe
shutdown earthquake for this site as defined in Appendix A to 10 CFR Part 100,
or its equivalent.
It should be noted that this disagreement over which event is the safe shutdown
earthquake has no bearing on plant safety since, whatever name is assigned to the
event, we require that the plant design be shown to be adequate for the Hosgri
event and the applicant is proceeding with the work necessary to demonstrate this.
It should also be noted that the horizontal acceleration values used above (0.2g,
0.4g and 0.75g) are given above for reference because they have been used in the
application and in the Safety Evaluation Report. However, taken alone, they are
not meaningful representations of the earthquake design bases. Many other factors
such as the shape of the associated spectra, the damping values used, the methods
of analysis, the load combinations employed and the allowable stresses or other
acceptance criteria are equally or more significant in seismic design. Furthermore,
the acceleration values themselves do not actually represent peak ground accelera-
tions from all the earthquakes considered (see Section 2.5.2 of Supplement No. 1
and Sections 2.5 and 3.7 of Supplements 4 and 5 for further discussions of the
acceleration values).
Operating Basis Earthquake
Three specific sections in Appendix A to 10 CFR Part 100 are pertinent to this
discussion.
(1) In Section V(a)(2), "Determination of Operating Basis Earthquake," the
regulation states that "...The maximum vibratory ground acceleration of the
Operating Basis Earthquake shall be at least one half the maximum vibratory
ground acceleration of the Safe Shutdown Earthquake.";
2-4
(2) In Section III, "Definitions," the regulation states that "The 'Operating
Basis Earthquake' is that earthquake which, considering the regional and
local geology and seismology and specific characteristics of local subsurface
material, could resonably be expected to affect the plant site during the
operating life of the plant..."; and
(3) In Section II, "Scope," the regulation states "If an applicant believes that
the particular seismology and geology of a site indicate that some of these
criteria, or portions thereof, need not be satisfied, the specific sections
of these criteria should be identified in the license application, and
supporting data to justify clearly such departures should be presented."
In line with these sections we have accepted, on several past cases, an operating
basis earthquake of less than one half the safe shutdown earthquake where
probability studies were used by the applicant to justify the operating basis
earthquake as being one that could reasonably be expected to affect the plant site
during the operating life of the plant.
As indicated above, although the applicant does not agree, we now consider the
Hosgri event to be the safe shutdown earthquake for this site, or at least its
equivalent. Accordingly, in a letter dated April 11, 1978, the applicant
described a justification for considering the design earthquake at O.2g to still
be the operating basis earthquake.%
The applicant has evaluated the exceedance probability of ground motion at the
site. The evaluations are contained in Reports D-LL 11, D-LL 28, D-LL 41 and
D-LL 45 in Appendix D to Amendment 50 and subsequent amendments to the operating
license application. Drawing upon these studies, the applicant has stated that
the design earthquake of O.2g has, as a conservative estimate, a probability of
14.5 percent of being exceeded during the projected operating life of the plant of
40 years. This corresponds to an average return period of about 275 years.
We have reviewed the applicant's analysis and have compared it with an independent
analysis performed by the staff's consultants, Dr. N. M. Newmark and Dr. A. Ang
(Reference 4, Appendix D to this supplement). While we do not fully agree with
all elements of the applicant's analysis and assumptions, we consider the results
to be reasonable and find them to be consistent with those derived independently
by our consultant. Moreover, the probability of the design earthquake is
consistent with the definition of the operating basis earthquake contained in
Appendix A to 10 CFR Part 100 and with past staff practice. We, therefore,
consider the operating basis earthquake ground motion with maximum acceleration of
0.2g to be acceptable for the Diablo Canyon site.
2-5
2.5.3 Slope Stability
Our evaluation of the stability. of the cut slopes adjacent to the plant, using the
plant's original seismic design basis, was provided in Section 2.5.3 of Supplement
No. 1 to the Safety Evaluation Report. We concluded that the slopes would remain
stable during the occurrence of the double design earthquake and that seismic
Category I structures would not be damaged.
Our evaluation of the effects of nearshore generated tsunamis was presented in
Section 2.4 of Supplement No. 5 to the Safety Evaluation Report. That evaluation
was based, in part, on our estimate of the maximum amount of breakwater slumping
that would be caused by the Hosgri event.
We have now updated our evaluation of the stability of the cut slopes to
correspond to the Hosgri event rather than to the original double design
earthquake. In addition, in order to check our previous estimate of breakwater
slumping for the Hosgri event, we have performed calculations based on the
expected ground motion and appropriate material properties. These evaluations are
described below.
In order to approximate the maximum deformation that could occur due to the
seismic event, we used the following procedure which, based on consideration of
the principles involved, we consider appropriate:
(1) The static factors of safety along the potential sliding surfaces having the
lowest margin of safety were obtained for the breakwater embankment section
and cut slope. Stability methods used for the breakwater included the
conventional method of slices and a check by the infinite slope method. The
static factor of safety for the cut slope was obtained from the Final Safety
Analysis Report.
(2) The effective earthquake assumed for computational purposes was the 1971 San
Fernando horizontal acceleration record at Paoima Dam (South 74 West record),
scaled and extended to correspond to the acceleration and duration values
given in Table 2 of Geological Survey Circular 672 (Reference 3, Appendix D
to this supplement) for a magnitude 7.5 earthquake.
(3) Using methods outlined by Newmark, 1965 (Reference 1, Appendix D to this
supplement) and Seed & Goodman, 1966 (Reference 2, Appendix D to this supple-
ment), the total displacements of the potential sliding surfaces were
computed. Yield accelerations (Seed & Goodman, 1966) were calculated from
the static factors of safety and displacements and were arrived at by the
double integration of the acceleration pulses exceeding the yield values.
For the breakwater analysis a constant yield acceleration was used. However,
based on direct shear tests, the yield acceleration for the cut slope
2-6
analysis was plotted as a function of displacement. A plot of this function
is provided by Harding-Lawson Associates in Appendix 2.5C of the Final Safety
Analysis Report. An embankment amplification factor of 2.0 was used for
acceleration pulses less than O.5g and a factor of 1.0 was used for
acceleration pulses greater than 0.5g.
In Supplement No. 1 to the Safety Evaluation Report, we and our consultant, the
U.S. Army Corps of Engineers, concluded that for the cut slope east of the power
plant the calculated maximum displacement was 10 inches. Our present analysis
shows an increase in estimated maximum displacement to 19 inches along the poten-
tial slide surface.
Since seismic Category I structures and equipment are about 30 feet removed from
the toe of the slope, this revised estimate of slope movement would have no effect
on safety. Accordingly, based on our review as described above and in Supplement
No. 1 to the Safety Evaluation report, we conclude that the movement of the slopes
during the occurrence of the Hosgri event will not damage seismic Category I
structures or equipment.
In our evaluation of nearshore generated tsunamis presented in Section 2.4 of
Supplement No. 5 to the Safety Evaluation Report, we stated that the applicant had
used an assumption corresponding to about 17 feet of vertical slumping at the
breakwater crest in calculating wave runup. Using conservative methods we had
determined that the crest of the breakwater would slump no more than five feet
vertically for the Hosgri event and, accordingly, concluded that the applicant's
assumption was conservative. The total displacement of the breakwater along the
potential slide surface resulting from the present analysis is approximately
three feet. This corresponds to less than three feet of vertical slumping at the
crest and is an improvement over the earlier five foot upper limit from the stand-
point of tsunami protection. Accordingly, our conclusions regarding tsunamis
remain unchanged.
We consider these matters resolved.
As discussed in Section 3.2.1 of this supplement, the applicant is qualifying the
raw water storage reservoirs as an extended source of auxiliary feedwater that
would be available to conduct a safe shutdown following the Hosgri event. As one
part of that review we will require analyses of the potential for slopes sliding
into the reservoir and information concerning the properties of the rock
underlying the reservoirs. We will provide our evaluation of these matters in a
future supplement to the Safety Evaluation Report.
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3.0 DESIGN CRITERIA - STRUCTURES. COMPONENTS EQUIPMENT AND SYSTEMS
3.2 Classification of Structures, Components and Systems
3.2.1 Seismic Classification
In Section 3.2.1 of the Safety Evaluation Report we presented our evaluation of
the applicant's designation of seismic Category I items (applicant's Design Class I).
These designations are contained in Table 3.2-4 and Figures 3.2-01 through 3.2-27
of the Final Safety Analysis Report. We found them acceptable.
The structures, systems and components that are being qualified for the Hosgri
event in the seismic reevaluation are described in the various chapters of the
Hosgri reevaluation report (Amendment 50 and subsequent amendments to the operating
license application). These plant features are those necessary to assure (1) the
integrity of the reactor coolant pressure boundary, (2) the capability to shutdown
the reactor and maintain it in a safe shutdown condition, or (3) the capability to
prevent or mitigate the consequences of accidents which could result in potential
offsite exposures comparable to the guideline exposures of 10 CFR Part 100. Since
the applicant has used current criteria in determining what items should be quali-.
fied, there are some differences between this set of items and the set that was
originally designated seismic Category I. We have reviewed the current designations
in two ways.
In the first review, we have applied our usual criteria as documented in Regulatory
Guide 1.29, "Seismic Design Classification," to determine the structures, systems
and comRonents that.need to be designed to withstand the effects of the Hosgri
event and remain functional. As in the original review, we have concluded that
structures, systems and components important to safety that are designed to with-
stand the effects of a Hosgri event and remain functional have been properly
classified in conformance with the Commission's regulations, the applicable
Regulatory Guide and industry standards. In accordance with our normal acceptance
criteria, qualification of these items for the Hosgri event provides reasonable
assurance that the plant will perform in a manner providing adequate safeguards
for the health and safety of the public with respect to earthquake safety.
In the second review, at our request, the applicant has considered in detail the
equipment and procedures necessary to achieve long-term cold shutdown conditions
after a Hosgri event, assuming that: (1) only equipment qualified for the event
would be available, (2) single failures may occur in that.equipment, and, (3)
offsite power may be lost for an extended period of time. The applicant's results
were submitted for our review in a letter dated January 26, 1978. Our evaluation
of this material is described below.
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For this event, the basic functions that must be performed following scram are:
(1) Heat removal
(2) Steam generator depressurization
(3) Primary system boration
(4) Primary system depressurization
(5) Surveillance of boron concentration
(6) Surveillance of primary and secondary system parameters
The following description represents one possible method for achieving cold
shutdown using only seismically qualified primary and backup equipment.
Electrical power for essential functions is provided by the plant's emergency
power system, including the batteries, diesel generators and vital distribution
systems. These features were originally designed for the double design earthquake
and to meet single failure criteria and they are qualified for the Hosgri event.
Initial heat removal will be through the steam generators using the auxiliary
feedwater system and releasing steam to the atmosphere by way of the safety valves
(hot shutdown conditions). The condensate storage tank is the primary source of
feedwater with about an eight-hour water supply. In order to ensure capability to
remove heat via the steam generators for extended periods, provisions have been
made to connect the raw water reservoir (minimum 1,000,000 gallons/unit) to the
suction line of the auxiliary feedwater pump. This will provide an additional 100
hours of steam generator operation for both units. As a further backup, design
provisions allow sea water from the auxiliary salt water system to be used as
auxiliary feedwater makeup if necessary.
The steam generators are depressurized to cool down the primary system.
Air-operated relief valves are used to depressurize the steam generators. The
primary system is depressurized by spraying cold borated water into the
pressurizer. This is accomplished with an auxiliary spray line connected to the
charging pumps in the chemical and volume control system.
After the primary system has been cooled down to 350 degrees Fahrenheit and
depressurized to 425 pounds per square inch, the residual heat removal system is
activated and the decay heat is transferred to the ultimate heat sink (the Pacific
Ocean) via the component cooling water and auxiliary saltwater systems. These are
cold shutdown conditions.
Boration of the primary system is performed with the chemical and volume control
system using two boric acid tanks having sufficient 12 weight percent boric acid
to borate the reactor coolant system for cold shutdown conditions. Provisions are
available for taking periodic, samples of the reactor coolant to confirm the boron
concentration.
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Normal instrumentation is available to maintain surveillance of important primary
and secondary system parameters such as pressure, temperature, and water levels.
The applicant has presented an analysis of the primary system water volume shrink-
age due to cooldown and has determined that the shrinkage is sufficient to accom-
modate chemical and volume control system input required for boration and cooling
of the pressurizer. Therefore, the normal letdown system is not required to
achieve long-term cooling with residual heat removal system. Similarly, the
applicant has demonstrated that degasification of the reactor coolant is not
necessary because the potential hydrogen concentration in the solution is less
than the saturation value at cold shutdown conditions.
All of the operator actions needed to perform plant cooldown (except for periodic
surveillance of the boron concentration) can be accomplished from the control room
assuming.no single failure. The applicant has demonstrated that redundant paths
or systems are available to perform the essential functions using qualified equip-
ment in the event of a single failure. In some instances this would require
operator action outside of the control room to activate the redundant path.
With regard to the residual heat removal system, the suction line is a single line
with two isolation valves in series. A failure that prevents opening these Valves
would prevent activation of the residual heat removal system for long-term cold
shutdown heat removal. An electrical failure could readily be corrected by manu-
ally actuating the valve(s). We were concerned about a possible mechanical failure
of one of these valves. The applicant addressed this question in a letter dated
January 26, 1978, maintaining that the probability of a valve disc separating from
the valve stem is low enough that it need not be considered in the single failure
study.
Based on our review of this matter we have concluded that this design feature is
acceptable for the reasons stated below. If mechanical valve failures of the type
that preclude opening the valves are considered to be random events, then the
probability of such failures occurring at the same time as a severe earthquake
does appear to be quite low. On the other hand, such failures may reasonably be
considered to be related to the earthquake. We do not believe that the prob-
ability of an earthquake causing the failures has been quantified. However, an
earthquake should not affect the valves since they are designed to withstand the
Hosgri event. Accordingly, although the combined probability level has not been
quantified, it is unlikely that a severe earthquake will occur in combination with
mechanical failures that preclude opening one of the two residual heat removal
system suction valves. Furthermore, if a severe earthquake should occur in com-
bination with mechanical failures that preclude opening one of the residual heat
removal suction valves, long-term heat removal can be accomplished indefinitely
with the steam generators and the auxiliary feedwater system rather than the
residual heat removal system. As a result, we consider the likelihood of this
failure in combination with its potential consequences to be acceptable.
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Since, without offsite power, the reactor coolant pumps could not be run to
provide reactor coolant system mixing, the applicant has committed to performing a
natural circulation test to demonstrate adequate boron mixing and acceptable
cooldown conditions using natural circulation. These tests will be performed
during startup when core heat is available.
The systems and equipment needed to perform these functions will be qualified for
the Hosgri event and have been included in the seismic reevaluation program which
is discussed in other sections of this supplement.
The following items are still outstanding in this portion of our review:
(1) A review of the system function indication available to the operator in the
control room in connection with performing the shutdown. (Section 7.5 of
this supplement)
(2) A review of the seismic qualification of the raw water storage reservoirs,
including:
(a) A review of the potential for seiches causing a significant loss of
water from the raw water storage reservoirs. (Section 2.4 of this
supplement)
(b) A review of the potential for slopes sliding into the raw water storage
reservoirs. (Section 2.5.3 of this supplement)
(c) A review of the properties of the rock underlying the raw water storage
reservoirs. (Section 2.5.3 of this supplement)
(d) A review of the provisions to ensure that the reservoir would not drain
through connected piping that is not qualified. (Section 10.5 of this
supplement)
We have reviewed the capability to cool the plant to cold shutdown conditions and
provide long-term cooling. The applicant has demonstrated that sufficient systems
are available for residual heat removal with or without offsite power and assuming
a single failure in accordance with Criterion 34 of the General Design Criteria.
Similarly, these systems will be qualified for operation in the event of the
Hosgri event in accordance with Criterion 2 of the General Design Criteria.
Accordingly, subject to satisfactory resolution of the outstanding questions
described above, we find these provisions acceptable.
We will provide our evaluation of the outstanding items discussed above in a
future supplement to the Safety Evaluation Report.
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3.3 Wind and Tornado Design Criteria
Background
In Sections 3.3 and 3.5 of the Safety Evaluation Report, we discussed the plant's
ability to withstand tornadoes. The plant's original design bases, as they were
approved in the construction permit review, did not include consideration of
tornadoes. During the operating license review, at our request, the applicant had
reviewed the existing design to determine the plant's resistance to tornadoes. We
had found plant tornado protection to be acceptable in the Safety Evaluation
Report.
Subsequently, in response to questions from the Advisory Committee on Reactor
Safeguards, we rereviewed this matter. As a result of our review and as discussed
in Section 3.5 of Supplement No. 6 to the Safety Evaluation Report, we requested
additional information from the applicant about some areas that might need upgrad-
ing. The applicant provided the additional information and made some
modifications. We have completed our review of the additional information and the
modifications. The results of our evaluation are presented below.
In the. sections that follow, where a wind speed is stated, it indicates the
maximum tornado windspeed (rotation plus translation). The results include the
effect of pressure drop and wind pressure.
Summary of Evaluation
The cable spreading and switchgear rooms associated with the emergency diesel
generators are designed to withstand a tornado with a windspeed to 200 miles per
hour, without missiles. However, they are vulnerable, in certain directions, to
damage by tornado generated missiles. Similarly, the main steam relief valve
spindles and some electrical cable trays constitute a smaller area that is vulner-
able, in certain directions, to tornado missile damage. We have concluded that
the probability of tornado generated missiles striking these limited vulnerable
areas is small enough to be negligible.
For the remainder of the plant, the tornado resisting capabilities have been
evaluated and vital equipment is protected against tornadoes (including missiles)
with windspeeds in excess of 200 miles per hour.
Further details of our evaluation are presented below.
Vulnerable Areas
A schematic layout of the cable spreading and switchgear rooms associated with the
diesel generators is provided in Figure 3-1 of this supplement. There are three
sets of rooms on the Unit 1 side of the turbine building. Two of these sets of
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rooms are associated with the two diesel generators dedicated exclusively to
Unit 1. The third set of rooms is associated with the swing diesel generator. On
the Unit 2 side of the turbine building there are two sets of rooms associated
with the two diesel generators dedicated exclusively to Unit 2.
The switchgear and cable spreading rooms on the Unit 1 side are only vulnerable to
tornado missiles from the north and east sides of the turbine building and those
on the Unit 2 side are only vulnerable from the south and east side of the turbine
building. The terrain east of the turbine building is hilly and thus affords some
protection. The east wall of the turbine building is substantially shadowed by
the containment structures of Units 1 and 2 (see Figure 3-1).
The switchgear rooms on the Unit 1 side are separated by walls of eight-inch
concrete blocks with all cells full of grout, number four reinforcing bars
vertically on 16-inch centers and two number four reinforcing bars horizontally on
32-inch centers. The same type of separation is employed in the cable spreading
rooms.
Separation between the rooms on the Unit 2 side originally consisted of plaster
fire walls. The applicant has agreed to upgrade those walls to reinforced
concrete block similar to the walls on the Unit 1 side. We consider this an
acceptable means of achieving the same degree of separation for Unit 2 as exists
for Unit 1.
In addition, the applicant has determined that the rooms can withstand the effects
of a 200 mile per hour tornado without missiles. The values associated with such
a tornado are as follows:
Maximum wind speed 200 miles per hour
Rotational wind speed 157 miles per hour
Translational speed 43 miles per hour
Total Pressure Drop 0.86 pounds per square inch
Rate of Pressure Drop 0.36 pounds per square inchper second
Girts are being added to the steel framing on the north, east and west sides of
the rooms to provide the exterior steel siding with this capability. We have
reviewed this design modification and find it acceptable.
In addition, some electrical cable raceways and electrical panels, located in the
vicinity of two of the four main steam lines for each unit, are vulnerable to
damage by tornado generated missiles. These items are shadowed from two
directions as indicated in Figure 3-2 of this supplement. Damage to the raceways
and panels could cause various malfunctions in the main steam system, the main
feedwater system and the auxiliary feedwater system.
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Finally, the main steam relief valve spindles are vulnerable to damage by tornado
generated missiles. The relief valves for two of the four steam generators for
each unit are almost completely shadowed by concrete structures. The others are
shadowed from two directions as indicated in Figure 3-2. The spindles are
extremely small targets.
Evaluation of Vulnerable Areas
The Diablo Canyon site is located along the central coast of California and is
located between the Pacific Ocean and the San Luis Mountain Range. The terrain is
rough mountain country. The climate of the site is maritime and severe weather is
not common in the area. Thunderstorms can be expected on only about three days
per year. The predominance of winds from the northwest and west-northwest in
conjunction with the mountain terrain assures good vertical mixing and the
presence of the Alaska Current offshore precludes the stratification of hot humid
air in the lower levels of the atmosphere in the region of the plant site.
A necessary condition for tornado formation is the stratification of hot humid air
in the lower levels of the atmosphere overridden by cold dry air with a lack of
vertical mixing which creates a mass density inversion. Also, tornadoes have been
observed to form in the north-west quadrant of rotating thunderstorms.
Using the methodology of WASH-1300, "Technical Basis for Interim Regional Tornado
Criteria," May 1974, to estimate local tornado occurrences indicates that for the
region of the plant site the design basis tornado windspeed (at a probability
level of about 1O-7 per year) is about 200 miles per hour. The data reported in
WASH-1300, however, show no reported tornadoes in the plant vicinity which
indicates that tornadoes are quite unlikely to strike a site in this region.
The assessment of tornado regions in WASH-1300 does not take into account the
local climatological or topographical conditions existing in the region. Given
the apparent lack of observed tornadoes in the vicinity of the plant, the physical
conditions at the site and the necessary conditions for tornado formation, it is
our conclusion that the probability that a tornado would strike the Diablo Canyon
site is small, and the probability of tornado generated missiles striking the
plant's small vulnerable areas is small enough to be negligible. On this basis we
have concluded that no additional tornado missile protection is needed for the
vulnerable areas.
Evaluation of the Remainder of the Plant
In the Safety Evaluation Report we discussed the analysis procedures used by the
applicant to evaluate the resistance of structures to wind and missile loads. We
found them acceptable.
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The applicant's review of plant layout is documented in Section 3.3 of the Final
Safety Analysis Report.
Most safety-related equipment is protected by concrete walls or enclosures capable
of withstanding the effects of a tornado with a windspeed of greater than 250 miles
per hour, including missiles. Significant exceptions, other than the vulnerable
areas discussed above, are summarized as follows:
(1) Auxiliary Building Louvers - The applicant has provided an analysis indicating
that failures in these louvers, which could affect air conditioning systems,
would not prevent a safe reactor shutdown.
(2) Condensate Storage Tank - A backup source of water is available in the raw
water storage reservoirs.
(3) Fire Water Storage and Transfer Tank - A backup source of water is available
in the raw water storage reservoirs.
(4) Refueling Water Tank - The applicant has provided an analysis indicating
that, in the event of tornado missile damage to the refueling water tank,
there would be sufficient reactor makeup water available from protected
sources to accomplish a safe reactor shutdown.
(5) Component Cooling Water System - The applicant has provided an analysis indi-
cating that, in the event of tornado missile damage to the exposed surge
tanks and piping on the auxiliary building roof, the system would still
operate satisfactorily.
We have reviewed the applicant's analyses described above and found them
acceptable.
Conclusion
Based on our review as described above and in the Safety Evaluation Report, we
have concluded that the probability of tornado generated missiles striking the
plant's small vulnerable areas is small enough to be negligible and the remainder
of the systems necessary to accomplish and maintain a safe reactor shutdown
following a tornado are protected and, therefore, the plant's protection against
tornado missiles is acceptable.
We consider this matter resolved.
3-8
3.5 Missile Protection Criteria
Turbine Missiles
In Section 3.5 of the Safety Evaluation Report, we stated that the design of
essential structures and vital equipment had taken into account, among other
things, internally generated missiles associated with component overspeed failures.
Specific staff positions regarding potential missiles from the main turbines had
not yet been developed and we had not performed a risk assessment for turbine
missiles.
As part of our evaluation of this subject we issued Regulatory Guide 1.115, "Protec-
tion Against Low Trajectory Turbine Missiles," in March 1976 for comment and a
revised version was approved in July 1977. In addition, we currently have underway
a generic task in this area. Since we are now performing turbine missile risk
assessments for all plants during construction permit and operating license reviews,
we have performed such an assessment for Diablo Canyon. Our evaluation is provided
below.
High trajectory turbine missiles (those missiles which are ejected in a nearly
vertical direction from a turbine generator) have a low strike probability density.
Our estimates of the strike probability density indicate that it is on the order
of 10-7 per square foot of horizontal target area. Our analyses of plants similar
to Diablo Canyon indicate that the total probability for high trajectory turbine
missiles damaging safety related systems and components is less than 10-7 per
turbine year. Thus, we have concluded that there is no significant risk to the
health and safety of the public due to potential damage by high trajectory turbine
missiles.
Since low trajectory turbine missiles are emitted within a relatively well-defined
angular range with respect to the turbine axis, Regulatory Guide 1.115 indicates
,that appropriate protection of safety-related structures can be achieved by place-
ment of the turbine so that its axis is peninsular with respect to other safety
structures. With this orientation, low trajectory turbine missiles are precluded
from striking safety-related targets. Although the guide recommends turbine
placement and orientation as the principal means of protection against turbine
missiles, it also recognizes that there may be circumstances such as plants under
review prior to the issuance of the guide where total exclusion of all
safety-related systems from the low trajectory turbine missile strike zones is not
feasible. In view of this the guide indicates that the probability for striking
and damaging vital systems which are located within the low trajectory missile
strike zones should be kept below 10-3 per turbine failure.
The Diablo Canyon Unit Nos. 1 and 2 turbine generators are arranged in a nonpenin-
sular configuration with respect to the containment building. Because of this
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configuration, portions of the reactor coolant system and the main steam system
inboard of the containment isolation valves are vulnerable to potential turbine
missiles in the event of a destructive overspeed failure of a low pressure turbine
disc. The turbine missile hazards to other safety-related structures are
insignificant since these structures are sufficiently protected by way of
placement or due to substantial shielding by existing structures (e.g., the spent
fuel poor, located on the opposite side of the containment with respect to the
turbine).
We performed a turbine missile risk assessment which considered the geometric
relationship of the turbine and the safety structures and which estimated the
solid angle subtended by these structures to arrive at a probability of a low
trajectory turbine missile striking and damaging these systems.
The containment wall is 3-1/2 feet thick and is composed of reinforced concrete
having a rated strength of 5700 psi. The steam generator enclosures containing
key primary and secondary coolant system components consist of an additional
two feet of similar concrete. Although these thicknesses are sufficient to stop
all missiles arising from a design speed failure (about 120% of rated turbine
speed) and some missiles arising from a destructive overspeed failure (about 190%
of rated turbine speed), it is insufficient to stop the more energetic missiles
resulting from a destructive overspeed disc burst.
Our analysis, based upon a destructive overspeed turbine failure rate of 4 x lO-5
per turbine year, and using the conservative missile penetration formulae recom-
mended in Regulatory Guide 1.115, Revision 1, yields a conservative value of
striking and damaging safety related systems of 8.4 x 10-6 per year. A more
realistic assessment, which takes into account the likely nondeflection of some of
the missiles emitted from the middle of the turbine, and also considers the possi-
bility of a two-piece turbine disc breakup model, results in a lower risk which is
estimated to be about 3.0 x 10-6 per year.
As a result of our analysis we concluded that the risks due to destructive overspeed
turbine missiles were low, although the values obtained were in excess of our
current acceptance criteria for new construction permit applications.
Our generic assessment indicates that a potential for a significant reduction in
the probability of occurrence of a destructive overspeed turbine failure can be
accomplished by means of improved turbine overspeed protection systems and steam
trip valve testing and inspection programs. Efforts are currently underway to
quantify the benefits of such programs. In addition, we believe that current
missile penetration formulae may be overly conservative. Experiments are currently
planned to test this perception.
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The above generic efforts reflect our view that our turbine missile analyses may
contain significant amounts of conservatism. Nonetheless, we consider it prudent,
in view of our continuing generic assessment in this area, to reduce the perceived
turbine missile risks. Accordingly, we have requested that the applicant commit
to a turbine-vendor-approved turbine steam valve testing and inspection program or
its equivalent which we will review for acceptability prior to a decision on
issuance of an operating license.
We have also considered the possibility of an earthquake disabling the turbine
overspeed protection system. In order to limit the probability of an earthquake
causing a destructive overspeed event, we have requested that the applicant provide
assurance that potential structural debris from an earthquake could not damage the
steam trip valves and ensure that the turbine building cranes not be in the vicinity
of the steam trip valves for any significant fraction of the time a turbine is
operating.
Subject to completion of the items cited above we conclude that the additional
margin provided by the steam valve testing program, the crane restrictions and the
structural debris protection will reduce the risk to a level comparable to our
current acceptance criteria, and we further conclude that with such programs theoperation of Diablo Canyon Unit Nos. 1 and 2 will pose no undue risk to the health
and safety of the public from turbine missile hazards.
We will report our evaluation of the applicant's response to the items discussed
above in a future supplement to the Safety Evaluation Report.
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3.6 Protection Against the Dynamic Effects Associated With the Postulated
Rupture of Piping
In Supplement No. 6 to the Diablo Canyon Safety Evaluation Report, we found the
Unit 1 design for postulated pipe failures outside containment acceptable.
However, there were proposed design differences between Unit 1 and Unit 2 - namely
the methods provided for protection against postulated breaks. We stated that we
would provide our evaluation for Unit 2 in a future supplement.
In a letter dated October 10, 1977, the applicant identified six areas where the
pipe break protection features on Unit 2 were different from Unit 1. The major
difference in protection on Unit 2 was that, for several locations, jet impinge-
ment barriers were eliminated from the Unit 2 design. However, for these
locations, safety-related equipment was separated from piping systems whose
failure could produce jets. This meets the guidelines of our Branch Technical
Position APCSB 3-1. Based on our review, we have concluded that the Unit 2 design
for the protection of safety equipment from the effects of postulated piping
failures outside containment meets the same criteria as stated in Section 3.6 of
Supplement No. 6 for Unit 1 and is acceptable.
We consider this matter resolved.
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3.7 Seismic Design
Original Seismic Design
In Section 3.7 of the Safety Evaluation Report, we discussed the applicant's
original seismic design methods and procedures and found them acceptable in rela-
tien to the original seismic design criteria. This conclusion has not been
changed.
With regard to the design earthquake or operating basis earthquake, we have con-
cluded in Section 2.5 of this supplement that the original operating basis earth-
quake remains unchanged for this site. Accordingly, there is no need for any
further work by the applicant with regard to operating basis earthquake design
matters.
Seismic Reevaluation
Section 1.0 of this supplement summarizes the background and history of the
seismic reevaluation. It also outlines the major aspects of this subject and
tells where they are discussed in various sections of this supplement.
A major part of the effort in the seismic reevaluation has been devoted to the
engineering analysis of structures, systems and components. These subjects are
discussed in the following two sections (Sections 3.8 and 3.9) of this supplement.
Although the applicant has completed most of the elements of the reevaluation,
numerous subtasks remain to be resolved to our satisfaction. We have completed
the major part of our review and many of the issues raised in this review have
been resolved. As a result of our review to date a fairly clear picture of the
plant's capabilities and the necessary modifications is evident.
In the following sections we often compare the methods used in the seismic
reevaluation with our current standard acceptance criteria. These comparisons can
facilitate evaluating the methods used. However, it is important to keep in mind
that the object of the reanalysis is to determine whether or not the plant can
safely withstand the Hosgri event. It is not necessary to meet all of the
standard acceptance criteria for new plants in order to determine acceptability.
Since the plant has been built it is possible to evaluate speci-fic situations such
as actual material strengths without providing the same allowances for possible
variations as are included in the standard acceptance criteria.
In a few individual cases, the applicant has demonstrated that the double design
earthquake loads determined from the original analysis are more limiting than
Hosgri event loads. This may at first appear confusing and raise a question as to
how the original can be so conservative as to exceed the Hosgri event loads. It
can happen in a few cases due to highly conservative assumptions or methods in the
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original analysis. In any event, if the applicant has used a load in the originaldesign and can now demonstrate that the Hosgri event load is less, we considerthis to be a sufficient load determination.
Where the original analysis is more limiting, the applicant has chosen not to takecredit for the lesser Hosgri event loads, but rather to use the more limiting
double design earthquake loads.
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3.8 Design of Category I Structures
3.8.5 Seismic Reevaluation
This section describes our review to date of the applicant's seismic reevaluation
of structures, outdoor tanks and buried pipe and describes the outstanding matters
that remain to be resolved.
3.8.5.1 Summary of Staff Review
Structural Specification
At a meeting on February 4, 1977, prior to performing the seismic reevaluation,
the applicant proposed a set of methods and criteria for the seismic reevaluation
of structures. These methods and criteria went into more detail than we had
specified in Supplements 4 and 5 to the Safety Evaluation Report. The scope of
these proposals included analyzing structures, evaluating their acceptability, and
developing seismic inputs for use in analyzing systems and components. It did not
include analyzing the systems and components. (Systems and components are dis-
cussed in Section 3.9 of this supplement). We discussed these proposals with the
applicant and, subject to some changes, we approved them. The methods and criteria
we approved were documented in our summary of the February 4, 1977 meeting and are
referred to here as the structural specification. A description and evaluation of
the resulting methods is provided below in Sections 3.8.5.2 and 3.8.5.3.
Remainder of Review
Pursuant to the structural specification the applicant has now reanalyzed the four
major safety related structures, namely, the containment structure, the auxiliary
building, the turbine building and the intake structure. In addition, the seismic
Category I water storage tanks, the underground diesel fuel oil tanks, and buried
piping have been reanalyzed.
In June 1977, the applicant submitted the results of a significant portion of the
seismic reevaluation in Amendment 50 to the operating license application. This
information has subsequently been supplemented by Amendments 53, 56, 59 and 60.
We reviewed Amendments 50 to 53 and requested numerous items of additional informa-
tion. The applicant responded to these requests in Amendment 56 in November 1977
and in several letters.
We reviewed the applicant's responses and then held seismic design criteria implemen-
tation meetings in the applicant's office during the week of January 16, 1978. At
these meetings we selectively reviewed the implementation of the structural and seis-mic design criteria for the plant. We also pursued questions regarding the appli-
cant's previous responses. The results were documented in our summary of the meet-
ings which included a lengthy list of areas where further information would be
required.
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To follow this up we held additional meetings with the applicant on February 8,
1978, February 16, 1978, February 28, 1978 and March 1, 1978. The applicant's
responses to outstanding items from the first meeting were discussed. The results
were documented in our summary of the meetings. The summary listed the areas that
still remained outstanding. These areas are, for the most part, still outstanding
and require resolution as discussed in the following sections.
Dur.ing this review, we have been assisted by our consultants, Dr. W. J. Hall and
Dr. N. M. Newmark. They have reviewed the applicant's principal submittals,
attended key meetings, made some independent estimates and provided advice on
critical areas. When our evaluation is completed we plan to provide their
recommendation in a future supplement to the Safety Evaluation Report.
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3.8.5.2 Ground Response Spectra
Spectra Approved in 1976
In Sections 2.5 and 3.7 of Supplements 4 and 5 to the Safety Evaluation Report,
issued in May 1976 and September 1976, we discussed the general criteria that we
had approved for use in the seismic reevaluation of the Diablo Canyon Plant.
These criteria went'primarily to the point of specifying the ground response
spectra to be used. Ground response spectra characterize earthquake ground motion
and are used as basic seismic design criteria for the structures to be analyzed.
Additional discussion was provided in a NRC staff report to the Advisory Committee
on Reactor Safeguards at the Committee's meeting on November 13, 1976 (Reference 5,
Appendix D to this supplement). Some further criteria, such as damping, were
discussed in that report and additional material regarding the rationale for our
criteria was provided.
Two sets of ground response spectra were involved in the criteria stated in
Supplements 4 and 5. One set had been developed by our consultant, Dr. N. M. Newmark
and the other had been developed by the applicant's consultant, Dr. J. A. Blume.
The approach, as it was stated at that time, involved (1) using the Newmark spectra
without any reductions for structural ductility or, alternately, (2) using the
Blume spectra, reduced by a simplified rule to account for structural ductility
ratios up to 1.3, provided the Blume spectra were then adjusted upwards as necessary
at various frequencies so that they never fell below the Newmark spectra. Where
ductility was utilized in this manner, precautions were to be taken to ensure that
seismic inputs to systems and equipment were not thereby underestimated. The use
of ductility with the Newmark spectra would, if necessary, be considered for
specific cases. Some of the spectra involved are illustrated in Figures 3-3
through 3-6. These figures are taken from the November 1976 staff report. They
show the horizontal ground response spectra that were approved for use in this
manner, as plotted for seven percent of critical damping. The spectra plotted for
other values of damping are contained in Chapter 3 of Amendment 50 to the operating
license application.
Our evaluation of the criteria discussed above was provided in Supplement No. 5 to
the Safety Evaluation Report. This was done by reference to Dr. N. M. Newmark's
report, in Appendix C to Supplement No. 5, which described the bases for the
spectra derived by Dr. Newmark. The November 1976 staff report to the Advisory
Committee on Reactor Safeguards discussed how the applicant's consultant
(Dr. J. A. Blume) had derived his spectra, compared the Blume spectra with the
Newmark spectra and indicated that the Newmark spectra would be limiting in most
cases.
3-17
Spectra Used in Reevaluation
In performing the reevaluation, the applicant has taken a more direct approach
than described above.
In the first place, adjustments for structural ductility were not made to the
ground response spectra as described above. Instead, where credit for structural
ductility is to be relied upon, it will be identified and justified for each
specific case. Where used, it will be accounted for in the design of individual
members rather than by reducing the ground response spectra. The only places
indicated to date where this might be done are the intake structure piers and the
end bents of the turbine building. These items, which remain outstanding in our
review, are discussed in more detail below.
In the second place, the Blume spectra and the Newmark spectra were both used by
performing separate calculations and using the more controlling result. For
horizontal analyses, the response quantities were computed for four earthquake
inputs, namely, the Blume and the Newmark Hosgri event inputs, each in the
north-south and east-west directions. For vertical analyses, the applicant found
that the Newmark Hosgri input was the governing one and, therefore, it was used in
the reevaluation.
Both the Blume and Newmark spectra have been reduced for large structures to
account for building size effects. This is illustrated in Figures 3-3 through
3-6. As discussed in Supplements 4 and 5 to the Safety Evaluation Report, this
reduction is associated with nonsynchronized ground motion waves under the struc-
tures, and where it is used, allowance has been made for torsion caused by such
waves. The methods for making this allowance are discussed further below.
In accordance with the usual practice, vertical ground motions were taken as two
thirds of the horizontal ground motions. No reduction for the effect of large
foundations was used for vertical motions.
This approach satisfies our criteria as stated in Supplements 4 and 5 to the
Safety Evaluation Report and is, therefore, acceptable.
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3.8.5.3 General Methods of Analysis
Description of Methods
A brief summary of the general analysis methods used in the seismic reevaluation
of structures is provided below.
The applicant employed ground response spectra as discussed in Section 3.8.5.2
above for ground motion input into the structures and outdoor tanks.
The analysis methods used for structures were generally the same as those used in
the original seismic design with the exception of the items listed below. This
constitutes a convenient way of describing the general analysis methods. Our
evaluation basis is, however, the conservatism of the methods - not a comparison
with the original method.
(1) The damping values recommended in Regulatory Guide 1.61, "Damping Values for
Seismic Design of Nuclear Power Plants," were used. Smaller damping values,
which yield larger calculated responses, were used in the original analysis.
Allowing the use of higher damping values in this reevaluation is realistic
and should not be regarded as an arbitrary lowering of the margins of safety.
The values given in the Regulatory Guide have been acceptable for several
years and are thus acceptable for this reevaluation.
Numerous studies have been conducted on this subject including (1) "Data on
Damping Ratios" by John A. Blume and Ahmad F. Kabir (Appendix DLL9 to Amend-
ment 50), (2) "Effect of Damping Variations," by John A. Blume, (Appendix
DLL17 to Amendment 50) and (3) "Notes on Approximate Relations for Sensitivity
of Design Spectra to Variations in Damping Factor and Ground Acceleration,"
by Nathan M. Newmark (Reference 10, Appendix D to this Supplement). In a
letter dated January 17, 1978 the applicant summarized the matter as it
relates to the use of 7 percent damping .for reinforced concrete structures as
recommended in Regulatory Guide 1.61. Among other things, this letter listed
the damping test data in relation to stress levels and summarized the calcu-
lated stresses for Diablo Canyon structures. These studies supported the
Regulatory Guide's recommended use of seven percent damping in lieu of the
five percent used in the original analysis for reinforced concrete structures.
Since the damping values used in the reevaluation of structures conform to
the recommendations of Regulatory Guide 1.61 and meet our current acceptance
criteria and, furthermore, based on our review of more recent studies including
those discussed above which support the adequacy of the values in the Regula-
tory Guide, we find the damping values used to be acceptable.
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(2) Average values of material properties, from tests of the actual materials
installed, were used to determine allowable stress levels instead of using
code specified minimum material properties. In the original analysis, code
specified minimum values were used in accordance with standard practice.
In our review we have found the use of actual material strengths acceptable
since some margin remains. For concrete, the appropriate average 28-day test
strength was used. Since concrete continues to gain strength with age after
28 days, the installed concrete will be stronger. For steel, average mill
test strength was used. Since the steel is ductile and the structures are
designed to remain below yield (with two possible exceptions as discussed
above), margin remains.
(3) Ductility (yielding) in structures was allowed in certain cases for the
reevaluation as described in Supplements 4 and 5 to the Safety Evaluation
Report, the November 1976 staff report to the Advisory Committee on Reactor
Safeguards and the structural specification.
In actuality, structural ductility has not generally been used in the
reevaluation; only two instances where it might be used have been identified
to date. These were noted above and are still under review. In any event,
where used, it will be justified for each specific case. We will review the
justification for each specific case and require that the amount of yielding
be kept within the limits set by the structural specification. We will also
require appropriate assurance that seismic inputs to systems and equipment
will not be underestimated due to structural ductility in such instances.
(This can readily be done by calculating the inputs to systems and equipment
separately, assuming the structure does not yield.) Subject to these
conditions we consider the use of structural ductility acceptable.
(4) Fixed base mathematical models were used for structures and above ground
tanks. A soil-structure interaction analysis, as was done in the original
analysis, is not necessary due to the stiffness of the rock foundation
material. In fixed base analyses, the ground motion is applied directly on
the base slab of a structure.
The fixed base analyses now being used are consistent with our current cri-
teria for rock sites such as the Diablo Canyon site. Since this methodprecludes the reduction of the ground motion that often results from
soil-structure interaction analyses using deconvolution and conforms to our
current criteria, we consider it acceptable.
The diesel fuel oil tanks, which are buried in soil, were not addressed in
the structural specification. Soil structure interaction analysis using a
finite element model was used for these tanks since it is appropriate for
items buried in and surrounded by soil.
3-20
The applicant has checked this analysis against another method described by New-
mark 1968 (Reference 9, Appendix D to this Supplement) and indicated that, in
this case, the soil-structure interaction analysis gives more conservative re-
sults than the other method. The Newmark method has been frequently used in
buried piping analyses. Since the tanks are buried in soil where soilstructure
interaction analyses would be appropriate and since the results have been checked
by a different method, we consider this approach acceptable for the diesel fuel
oil tanks.
(5) As discussed in Section 3.8.5.2 above, the horizontal ground response spectra
were reduced somewhat to account for foundation size effects in relation to
ground motion waves (nonsynchronized ground motion). As stated in Supplement
No. 4 to the Safety Evaluation Report, we feel that, where such credit is taken
in relation to the usual procedure of assuming synchronized ground motion, an
appropriate consideration of other effects of nonsynchronized ground motion
such as torsion should also be included.
This was accomplished by assuming an artificial eccentricity between the center
of mass and center of rigidity of the building. This is above and beyond any
actual (geometric) eccentricity which was also computed and accounted for. The
effect of this artificial eccentricity is to force the horizontal ground motion
that is used in the analysis to create additional torsional motions about the
vertical axis.
An eccentricity of five percent or seven percent of the width of the structures
was assumed, depending on the technique used to combine the torsional with the
translational responses. This was in addition to any actual eccentricity of the
structures. The five percent eccentricity was used when the torsional and trans-
lational responses were combined by the absolute sum rule, and the seven percent
eccentricity was used when the two responses were combined by the square-root-of-
the-sum-of-the-squares rule. The greater of the combined responses was used in
the reevaluation. The five percent absolute sum method was the more limiting of
the two cases discussed above.
With regard to floor response spectra, the torsional floor response spectra at
the center of mass were calculated using actual (geometric) eccentricity of the
structure in addition to an assumed eccentricity equal to 5 percent of the struc-
tural dimension. The Blume and Newmark torsional spectra multiplied by the dis-
tance between the center of mass and the location of interest were combined on
an absolute sum basis with the horizontal spectra described above. This combina-
tion yielded equivalent horizontal floor response spectra at the point being
considered.
These are approximating techniques and represent a step towards more realistic
modeling of structural responses. In light of this and based on the advice of
our consultant, Dr. N. M. Newmark, we find the methods discussed above to be
acceptable.
3-21
(6) A vertical response dynamic analysis was performed rather than assuming an
invariant vertical acceleration throughout the structures as was done in the
original analysis.
The vertical dynamic analysis used is more accurate since, if any structure8
have sufficient vertical flexibility to cause amplification of vertical
motions, the analysis will so indicate. If not, the result will be the same
as assuming invariant vertical motion. The vertical dynamic analysis is
consistent with our current criteria and is, therefore, acceptable.
(7) A modified procedure was used for smoothing the raw floor response spectra.
For the reevaluaton, smoothing was done by free-hand averaging of floor
response spectra except at the peaks where it was widened by 15 percent on
the low frequency side and five percent on the high frequency side without
reduction of the peaks. In the original analysis the peaks were broadened by
10 percent on both sides after being lowered by 10 percent.
The purpose of widening the peaks is to account for possible variations in
the predicted structural frequencies. Our current criteria indicate widening
by 15 percent on both sides of the peaks. However, since actual material
strengths are being used in the reevaluation, the calculated structural
stiffness is closer to the maximum stiffness than usual, indicating a lesser
need for peak broadening on the high frequency side. For these reasons we
consider the current approach acceptable.
(8) In combining structural responses at each point, responses due to horizontal
excitation in two directions were combined with the response due to vertical
excitation by the square-root-of-the-sum-of-the-squares rule. In the original
analysis one response due to horizontal excitation and one response due to
vertical excitation were combined by the absolute sum method. The process
was repeated for the other horizontal component and the more limiting result
was employed for design.
The current approach corresponds to the recommendations of Regulatory Guide
1.92, "Combining Modal Responses and Spatial Components in Seismic Response
Analysis," December 1974. It is consistent with current criteria and we
consider it acceptable.
Evaluation of Methods
Several conservative elements are inherent in the procedures normally used in the
seismic design of nuclear power plant structures. They have been extensively
discussed in various forums. The general methods of analysis used by the applicant
in the seismic reevaluation as outlined above contain three significant relaxations
relative to the normal, or currently accepted, procedures. One relaxation is the
3-22
reduction of ground response spectra to account for building size effects. The
second is use of actual material strengths rather than code specified minimum
material strengths. The third is allowance for ductility in structures which
might be used in two specific cases and specifically justified. As discussed
above and in Supplements 4 and 5 to the Safety Evaluation Report and in our
November 1976 report to the Advisory Committee on Reactor Safeguards, we believe
these relaxations are justified. The other usual conservatisms still apply.
Thus, based on our review, we conclude that, taken as a whole, the general methods
and procedures outlined above are conservative and provide for adequate safety
margins in the design of Category I structures.
3-23
3.8.5.4 Structural Analysis
This section discusses our evaluation of the applicant's methods for analysis of
the various structures, outdoor tasks, buried piping and cranes. The applicant's
methods and the outstanding items in our review are described in subsections
3.8.5.4.1 thorugh 3.8.5.4.8. Our conclusions are presented in subsection 3.8.5.4.9.
3.8.5.4.1 Containment Shell
The reactor containment shell is a cylindrical, reinforced concrete structure
which consists of a 142-foot high cylinder, topped with a hemispherical dome. The
cylinder wall is 3 feet 8 inches thick, and the dome is 2 feet 6 inches thick.
The inside diameter is 140 feet. The base is a circular slab 153 feet in diameter
and 14 feet 6 inches thick, with the reactor cavity near the center. The inside
of the shell is lined with welded steel plate which forms a leaktight membrane.
The liner is 3/8-inch thick on the wall and dome and 1/4-inch thick on the base
slab.
Since the containment structure is founded on a rock medium, soil-structure inter-
action effects were considered negligible. Accordingly, for the reevaluation, the
containment structurewas assumed to be fixed at the base and the exterior and
interior structures were uncoupled for analysis purposes since they are not coupled
or laterally connected at any elevation except the base.
An axisymmetric model was used to compute the translational response of the shell
due to the horizontal component of the ground motion. Since the center of mass
and the center of rigidity coincide, the translational analysis did not yield any
inherent torsional modes or responses in the shell. Peak responses and acceleration
time-histories were determined for various nodes using the time-history modal
superposition method.
In accordance with the general methods discussed above the torsional response due
to horizontal inputs was determined using a time-history modal superposition
method. Two lumped mass models were used assuming an accidental eccentricity of 5
percent and 7 percent, respectively, of the structural dimension in the direction
perpendicular to the applied load. The torsional response from the two lumped
mass models were combined with the corresponding horizontal translational responses
from the axisymmetric model in accordance with the general methods discussed above
in Section 3.8.5.3 above. The applicant has demonstrated the equivalency of the
axisymmetric model and the lumped mass model by comparing the natural frequencies
and participation factors of the two models.
Vertical acceleration and displacement responses were determined by a time-history,
modal superposition analysis of the axisymmetric finite element model.
3-24
The maximum shell forces and moments were determined by a response spectrum analysis
of the same axisymmetric model.
The appropriate responses from the horizontal and vertical components of the
ground motion were combined at the mid-thickness of the shell using the square-root-
of-the-sum-of-the-squares rule.
Raw floor response spectra for both the Blume and Newmark inputs were computed
from the acceleration time-history responses at various nodes of the containment
shell.
To develop the horizontal floor response spectra, the translational spectra were
combined with the torsional spectra using the method described above in Section
3.8.5.3. The resulting spectra were then combined on a square-root-of-the-sum-of-the-
squares basis with the horizontal component due to the vertical input to yield the
design spectra. The horizontal floor response spectra are applicable in any
horizontal direction due to the symmetry of the structure.
The vertical floor response spectra were generated based on a dynamic vertical
analysis of the exterior structure. These raw floor spectra were calculated for
the various damping values appropriate to different equipment and were smoothed in
accordance with the general methods discussed above in Section 3.8.5.5. These
floor response spectra were then used in the reevaluation of components, pipes and
electrical conduits attached to and supported by the containment shell.
Since the containment shell was originally qualified for a O.4g double design
earthquake, the applicant has reevaluated the adequacy of the containment shell by
comparing the resulting forces to those obtained from the original analysis. This
was accomplished in three steps:
(1) Systematic review of all the original design calculations to extract and
summarize the results of the seismic analysis.
(2) Comparison of the Hosgri event dynamic analysis results with the original
dynamic analysis results to identify the potential problem areas, and
(3) Detailed evaluation of areas identified as potential problems.
The areas listed below remain outstanding in our review of the containment shell
and require resolution. We will provide our evaluation of these matters in a
future supplement to the Safety Evaluation Report.
(1) An evaluation of containment stability against overturning and uplift.
Although the peak horizontal and vertical forces disturbing the structure are
large, actual overturning of the containment is physically impossible due to
3-25
the oscillating nature of these forces. However, we will require considera-
tion of the amount of tilting that may be possible (without overturning) in
order to ensure that it would not damage safety-related equipment or structural
elements (for example by overstressing piping connected to the containment
shell). The applicant has submitted an analysis of the amount of tilt which
we are reviewing.
(2) Further analysis of the foundation mat. Because of its massive character and
thickness the applicant assumed that the foundation mat would not be affected
by the increased loads due to the Hosgri event and did not reevaluate it for
the new earthquake. We requested that the applicant perform a simplified
analysis using conservative assumptions to assure that the base mat would not
be overstressed. The applicant submitted a simplified analysis which we
found unacceptable because we did not agree with the basic assumptions. The
applicant has committed to revise the analysis and to ascertain the adequacy
of the foundation mat during a Hosgri event.
(3) An evaluation of the criteria and methods for screening critical elements and
a complete list of these elements and their problem areas. We requested that
the applicant correlate the information presented in Amendment 50 and more
clearly describe the procedure used to determine which structural elements,
if any, had to be redesigned and modified to resist the forces imposed by the
Hosgri event. This information has been submitted by the applicant and we
are reviewing it.
(4) An evaluation of the containment penetration design. During the meetings the
week of January 16, 1978 we requested that the applicant demonstrate adequacy
of the penetrations in the containment shell for the Hosgri event. We were
concerned about whether the discontinuity stress in the shell around the
penetration would be increased beyond the acceptable limits due to the earth-
quake. The applicant has provided pertinent information and we are reviewing
it.
(5) Further analysis of the stresses in diagonal reinforcement of the containment
shell. We are currently discussing with the applicant the method of combining
peak seismic loads for the containment shell diagonal reinforcement. We have
requested additional studies in order to make a judgment on this matter.
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3.8.5.4.2 Containment Interior Structures
The containment Interior Structures consist of two concentric concrete walls with
outside radii of 53 feet and 17 feet respectively. The inner cyl)indrical wall
varies in thickness from three feet to 8.5 feet; it supports the reactor vessel.
The outer cylindrical wall houses the steam generators, the reactor coolant pumps,
the pressurizer, and other equipment. Concrete slabs provide horizontal diaphragm
stiffening action at elevations 114 feet and 140 feet. A polar gantry crane is
mounted on top of the outer cylinder wall. The interior and exterior structures
are supported by a common heavy concrete base slab of 14.5 feet thick for most
part of the slab except the reactor cavity area where the slab is nine feet thick.
An equivalent axisymmetric model of the interior structures was used in the analysis.
The modelwas assumed fixed at the base. Because some of the shear walls are notsymmetrical about the structural axis, the axisymmetric shell elements were estab-
lished on the basis of the equivalent cross-sectional properties of the structure.
Small irregularities in the foundation slab were neglected. The equivalent mass
density used for each element reflects the mass of attached mechanical equipment
and all other associated masses, as well as the concrete mass density.
A time-history modal superposition analysis of the axisymmetric model was used to
compute the translational response of the structure due to the horizontal component
of the ground motion. Because the center of mass and the center of rigidity of
the model coincide, the translational analysis does not yield any inherent torsional
modes or responses in the structure.
For the torsional response due to horizontal inputs, a time-history, modal super-
position analysis of two lumped-mass models was performed. Again, the lumpedmasses represented the accumulated mass of the concrete structure, the steel fram-
ing, the equipment, the reactor and the other masses.
The center of rigidity and the center of mass of the interior structures are
approximately coincident for the east-west ground motion but are separated by one
foot between elevations 114 feet and 140 feet and 2.5 feet between elevations 91
feet and 114 feet for the north-south ground motion. Because the eccentricities
for the north-south ground motions are the larger, the torsional response to that
motion was calculated and used for both orthogonal horizontal directions.
Vertical responses were determined by a time-history, modal superposition analysis
of the lumped-mass model. A coupled model incorporating both the concrete interior
structure and the steel annulus structure was used for the analysis.
At our request the applicant established the equivalency of the axisymmetric model
and the lumped-mass model by comparing the dynamic characteristics of the two
models. The difference was insignificant.
3-27
Raw horizontal and torsional response spectra for both the Blume and Newmark
inputs were generated from the acceleration time-histories at various elevations
along the center line of the interior structure. These response spectra were used
for both the north-south and the east-west directions due to the assumed axisymmetry
of the structure. Equivalent horizontal response spectra at the location of
interest were developed using the method described previously.
The raw vertical floor response spectra were generated based on a dynamic vertical
ahalysis of the interior structure.
The above raw floor response spectra were calculated for various values of damping
appropriate for systems and equipment and were smoothed according to the procedures
discussed above in Section 3.8.5.3. The smoothed horizontal and vertical floor
response spectra were used for the reevaluation of systems and components.
The same procedure used in the containment shell analysis for identifying problem
areas was followed in the evaluation of the containment interior structures, i.e.,
review of original calculations, comparison with Hosgri analysis and evaluation.
It was found by the applicant that the stresses resulting from the Hosgri event
were all within the allowable limits set forth in the structural specification
except for some structural members in the annulus which are discussed further in
item (4) below.
The areas listed below remain outstanding in our review of the containment interior
structure and require resolution. We will provide our evaluation of these matters
in a future supplement to the Safety Evaluation Report.
(1) Further calculations regarding the equivalent stiffness of the interior
structure. We requested that the applicant provide a study to determine the
change in the dynamic characteristics of the interior structures of the
containment due to different modeling techniques. The purpose of this study
was to determine the effect of employing the axisymmetric model used in the
translational analysis rather than a model which would incorporate the-stiff-
ness characteristics of the actual structures. The applicant provided us
with comparison of the results of the analyses using two models reflecting
the two conditions, each consisting of two masses. Although periods of the
two models are practically identical, we will require more information
regarding the details of the analyses in order to make a determination on
their validity.
(2) Evaluation of the justification for decoupling. In the reevaluation of the
containment interior structure the applicant included the masses of major
equipment such as steam generator and reactor vessel but ignored their stiff--
nesses. Since the mass of this type of equipment is large compared to the
mass of the supports the vibrations of one may affect the other. For these
3-28
reasons we requested that the applicant provide a justification for decoupling
of the equipment from its support. The applicant has provided this informa-
tion and we are reviewing it.
(3) An evaluation of the analysis of the internal structures (distribution of
shear and bending moments). In general, sheer forces induced into the struc-
tural system are resisted by the piers and walls. Distribution of lateral
forces among individual piers is a function of the relative stiffness in
bending and shear. The applicant used a rought assumption regarding the
distribution of shears and moments between interior structures and the crane
wall. We requested quantitative justification for this assumption. The
applicant has provided a justification and we are reviewing it.
(4) An evaluation of the annulus area. Initially, at the meetings during the
week of January 16, 1978, the applicant informed us that the loads assumed
for the reevaluation of steel members in the area of annulus between the
exterior shell and the crane wall were twice the loads of the double design
earthquake. In spite of such a seemingly high assumed load the applicant
found that, for some of the members, loads determined by a Hosgri event
analysis would be higher. Since that time the applicant has provided us with
a list of all the members in the annulus area comparing the loads resulting
from the twice double design earthquake assumption and from the Hosgri event
analysis. We are reviewing this information. We also expect the applicant
to submit a report describing the remedial action to. be taken and a sample of
redesign of individual members.
3-29
3.8.5.4.3 Auxiliary Building
The auxiliary building is a reinforced concrete, shear wall box-type structure
except for the fuel handling area which is a steel structure. The shear walls are
generally three feet thick, with a minimum thickness of two feet. $labs are
generally two feet thick. The walls of the spent fuel pools are a minimum of six
feet thick except for local areas around the fuel transfer tubes. The foundation
slab under the spent fuel pits has a minimum thickness of five feet. The sides
and bottoms of the spent fuel pools are lined with stainless steel plate, 1/4-inch
thick on the bottoms and 1/8-inch thick on the sides.
The main floor levels in the auxiliary building are at elevations 60, 73, 85, 100,
115 and 140 feet. Elevations 60 and 73 feet are below ground level, which is at
elevation 85 except for the east side of the building where ground level is at
elevaton 115.
The only connections between the auxiliary building and other structures are the
fuel transfer tube and miscellaneous piping. The fuel transfer tube is fitted
with expansion bellows which allow relative movement between the auxiliary building,the containment shell, and the containment internal structure. The design of the
expansion bellows considers the maximum axial and lateral relative deflection thatcould occur during the Hosgri event. The design of miscellaneous piping is dis-
cussed in Section 3.9 of this supplement.
The auxiliary building was analyzed for the three components of the Hosgri event
ground motion using a modal superposition time-history procedure. Peak responses
were calculated, and acceleration time histories were determined for various nodes
for use in determining raw floor response spectra.
Three different mathematical models of the auxiliary building were used for anal-
yses: one in the north-south direction, one in the east-west direction, and onein the vertical direction. The models were assumed fixed at the elevation 85 feet
(i.e., ground motion input was applied into the structure at this elevation).
All degrees of freedom have been defined at the center of mass. Part of the
structure between elevations 60 feet and 85 feet is below grade and was not lumped
as a separate mass but was assumed to be part of the foundation soil mass.
To account for the embedment effect of the upward-sloping grade above elevation 85feet a set of equivalent spring stiffnesses were determined based on the elastic
half-space theory. These stiffnesses were then increased to account for the
effect of a sloping surface on the east side of the buildig. At our request the
applicant performed a parametric study by varying the stiffness values. The
applicant demonstrated that the variation of the stiffness values has little
effect on the structural responses.
3-30
Locations of the centers of mass and rigidities were calculated for each level to con-
sider the torsional mode of vibration in the analysis. The actual (geometric) eccen-
tricities combined with five percent assumed accidental eccentricities have been in-
cluded in the model for the north-south ground motion. For east-west analysis, the
auxiliary building was considered symmetrical and, therefore, only accidental eccen-
tricities were included in the model.
To establish whether the five percent or the seven percent assumed accidental eccentri-
city gave the higher responses, the results from the two methods discussed previously
were computed. The applicant indicated that the absolute sum of the horizontal re-
sponse and the torsional response due to the five percent assumed eccentricity in every
case gave higher values than the square-root-of-the-sum-of-the-squares combination of
the horizontal response with the torsional response due to the seven percent assumed
eccentricity.
For vertical analysis the model was based on the assumption that the floor slabs were
rigid (i.e., have fundamental frequencies higher than 33 Hertz). This assumption
holds for all auxiliary building floor slabs except the floor of the control room.
The control room floor was modeled by finite elements. The wall and column supports of
the slab were assumed to be rigid in the vertical direction; rotational degrees of free-
dom were modeled by springs whose rotational stiffness was equal to that of the walls.
The smoothed horizontal, torsional and vertical floor response spectra for damping
values appropriate to systems and equipment were developed from raw spectra deter-
mined from the acceleration time histories at various nodes. The spectra were
defined at the actual (geometric) centers of mass in the building. The horizontal
and torsional spectra given are for the controlling case of five percent accidental
eccentricity.
No torsional spectra were given for the roof of the steel structure over the fuel-
handling area (elevation 188 feet). Torsional effects were accounted for by increas-
ing the north-south and east-west horizontal response at this level by 10 percent. We
will require further information to confirm that this is equivalent to or more conser-
vative than using the five percent assumed eccentricity to account for torsion. We will
provide our evaluation of this matter in a future supplement to the Safety Evaluation
Report.
Adequate safety margins have been provided by consideration of the additional strength
resulting from reinforcing bar in excess of original design requirements and from act-
ual average values of material properties. The maximum calculated compressive stress
in the concrete ranges from 300 to 1500 pounds per square inch which is well below the
allowable stress of 3920 pounds per square inch. The average safety factor for rein-
forcing steel is about 1.5. Safety factor defined here is the ratio between yield
stress and computed stress.
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In analyzing the shear keys in the foundation below elevation 85 feet, the applicant
used a coservative approximate method that resulted in overstressing.
Consequently, we requested a more accurate analysis. The applicant has submitted
further information and we are reviewing it. Our evaluation will be provided in a
future supplement to the Safety Evaluation Report.
In the process of investigation of the soil bearing pressure under the auxiliary
building the applicant confined himself to the lowest levels which are at elevation
57 feet. Because of the shape of the building (Tee shape) we feel that the bearing
pressure should be checked also at the outermost points from its centroid, although
it may be at a higher elevation. The applicant has agreed to investigate the
bearing pressure at such a point, elevation 85 feet. We will provide our evaluation
of this matter in a future supplement to the Safety Evaluation Report.
A comparison of the Hosgri event dynamic analysis with the double design earthquake
results was made to identify those floor slabs that have the highest percentage of
increase in response and the least reserve capacity. A detailed reevaluatin
showed that the slabs are adequate to withstand the Hosgri event. The maximum
moment in the slabs was found to be within the code allowable ultimate capacity of
the slabs.
The areas listed below remain outstanding in our review of the auxiliary building
and require resolution. We will provide our evaluation of these matters in a
future supplement to the Safety Evaluation Report:
(1) Demonstration of the conservatism of the method used to account for torsional
effects in the roof of the fuel handling area (discussed above).
(2) An evaluation of the analysis of shear keys in foundations (discussed above).
(3) Further analysis of soil bearing pressure (discussed above).
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3.8.5.4.4 Intake Structure
The intake structure is a reinforced concrete shear wall building constructed with
3000 pounds per square inch minimum-specified-strength concrete. Except for the
auxiliary saltwater conduits, water-tight doors and ventilation it was not original-
ly classified as seismic Category I. However, it was analyzed to assure protection
of the auxiliary salt water system in the event of an earthquake and it has been
evaluated for the Hosgri event.
The structure is approximately 205 feet long by 100 feet wide. The long dimension
corresponds to the north-south direction, as assumed in the analysis, and is
parallel to the seaward face of the structure. The intake structure is surrounded
by rock backfilled on three sides, while the fourth (western) side is exposed to
the Pacific Ocean. The top deck of the structure has a maximum elevation of +17.5
feet. A small concrete ventilation tower extends to an elevation of +31.0 feet.
The structure is supported by a concrete mat foundation at an elevation of -31.5
feet. The top level of the structure consists of a concrete slab 18 inches thick.
At elevation -2.1 feet, the pump deck floor supports the four main circulating
water pumps and the four seismic Category I auxiliary saltwater pumps. Water for
these pumps is brought in through the exposed western (ocean) side of the struc-
ture. The structure is symmetric about a vertical plane in the east-west direction
through its centerline. The ocean side of the structure at the level of -2.1 feet
has no floor diaphragm and is connected to the land side of the structure by a
thick, vertical north-south shear wall running from elevation -7.7 feet to the
top-deck level. At the top-deck level, this wall is connected, through an 18-inch
thick horizontal diaphragm with numerous openings, to the remaining 18- and 24-inch
thick slabs over the pump area.
The seismic analysis of the intake structure was carried out by initially separat-
ing the structure into two basic parts: (1) the pump deck base, consisting of the
massive land-side portion of the structure, from elevation -31.5-foot to the
-2.1-foot pump-deck level; and (2) the remainder of the structural system. The
pump-deck base was considered to be the ground for the analysis of the remainder
of the structure.
Three three-dimensional mathematical models were developed to model the structure:
an east-west model, a north-south model, and a vertical model. Each model is
structured so as to represent the vibrational response characteristics of the
structural system due to seismic input in the corresponding direction. All three
models use typical finite-element methods of suitable for the structural system.
For all models, the floor slabs and most vertical walls were modeled as flat-plate
elements to include both membrane (in-plane) and bending (out-of-place) behavior.
Some thick shear walls near the symmetry plane of the structure in the east-west
direction have been modeled as three-dimensional solid elements.
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Provision for accidental torsion was taken into account by assuming a torque
equivalent to the total base shear multiplied by five percent of the long dimen-
sion of the structure.
Only those modes with frequencies of oscillation less than or equal to 33 Hertz
have been considered significant for response computations. The fundamental
frequencies of the system in the north-south east-west and vertical directions are
10.4 Hertz, 25.6 Hertz and 16.0 Hertz, respectively. Shear stresses in the walls
due to the east-west earthquake are within the allowable 120 pounds per square
inch of the concrete alone.
Based on the low magnitude of the stresses in the elements of the structure, we
have concluded that there is no danger of structural damage from east-west earth-
quake forces.
For the north-south earthquake the seaward piers have been found to be considerably
overstressed. We have requested that the applicant perform additional work using
a more refined method of analysis and submit the results for our review. If this
analysis is to demonstrate that the piers, as they are, will not fail it will
undoubtedly be through credit for structural ductility. In this event we will
review the justification and ensure that the amount of yielding is confined to the
limits previously set forth by the structural specification. Alternately, there
is another option, short of modification, that the applicant might pursue. That
option would be to demonstrate that, despite failure of the piers, operation of
the auxiliary seawater system would not be impaired.
We have not accepted the stability analysis initially provided by the applicant
and have requested a more realistic assessment of the sliding resistance and
overturning resistance. We are currently reviewing the applicant's response.
The areas listed below remain outstanding in our review of the intake structure
and require resolution. We will provide our evaluation of these matters in a
future supplement to the Safety Evaluation Report.
(1) Further justification for dynamic earth pressure calculations. In estimating
the increase in earth pressure due to the earthquake the coefficient of
dynamic pressure was used without any reference or backup information. This
coefficient has been evaluated by various investigators and it is well known
that it may vary over a wide range depending on such factors as source, soil
conditions and level of water table. Thus, it is important that the selected
value be justified. Furthermore, since the soil pressure varies directly
with the coefficient it may affect the stability of the structure against
sliding which, if excessive, could be damaging to the safety-related piping
and equipment. For these reasons, we will require that the applicant provide
us with justification for the increase in lateral pressure due to an earthquake.
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(2) Further analyses of piers (discussed above).
(3) An evaluation of the foundation mat analyses. We found an error in the
applicant's analysis of the mat which resulted in an excessive ductility
ratio. We notified the applicant and he has performed another analysis to
correct the original error. We are reviewing this submittal.
(4) Further stability analyses. In the calculation of the factor of safety
against sliding the applicant took credit for an excessive amount of depres-
sion of the concrete structure into the rock which would act as a shear key
and thus prevent sliding. The design drawings indicate that the actual
depressed area is less than the area used in the analysis. This would result
in a reduced resistance to sliding and, consequently, a lower factor of
safety. The applicant has submitted a new analysis which used a more
realistic depressed area and we are reviewing it. In addition, although the
actual overturning of the structure is virtually impossible because of the
oscillating nature of the disturbing forces, it must be assured that this
structure does not tilt enough to damage the safety-related equipment. We
will require that the applicant analyze this aspect of stability of the
structure.
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3.8.5.4.5 Turbine Building
The turbine building was not originally designated as a seismic Category I
structure. However, it contains some seismic Category I equipment - principally
the emergency diesel generators, associated vital switchgear, and the component
cooling water heat exchanger. Early in the operating license review., in response
to our request for assurance that this equipment would be protected from
earthquakes, the applicant adopted the approach of performing dynamic seismic
analyses for the entire structure as would be done for a Category I structure.
The same approach has been followed in the seismic reevaluation.
It is worth noting that, since this structure was not originally designated
seismic Category I, it initially met design earthquake criteria rather than double
design earthquake criteria. This explains, at least in part, why the turbine
building now appears to require more extensive modification than the other major
structures.
The turbine building is a combined steel frame and concrete structure in which a
combination of vertical X-bracing and reinforced concrete shear walls provides
lateral force resistance. Unit I is a long rectangular building approximately
400 feet long in the north-south (longitudinal) direction and 140 feet wide in the
east-west (transverse) direction. Unit 2 is similar. The building consists of
four working floor levels approximately at elevations 140, 119, 104, and 85 feet,
with grade being located at elevation 85 feet. The massive reinforced concrete
turbine pedestal, which supports the turbine generator, is located in the center
of the building. This pedestal has been structurally isolated from the floors at
elevations 140, 119, and 104 feet, but it does share a common foundation mat with
the building. Two 115-ton-capacity overhead cranes will operate at elevation 180
feet.
The roof is supported by trusses spanning approximately 138 feet These are con-
nected by moment-resisting connections to 40-inch deep welded plate columns to
form rigid bents in the east-west direction. The various bents are tied together
at the roof level with the lower-chord bracing system and at elevation 140 feet,
by the floor framing and concrete diaphragm slab. The welded plate columns of
each bent extend from approximately elevation 85 feet up to the roof trusses.
The north-south, east-west, and vertical analyses of the turbine building were
decoupled to facilitate the analysis of the structurally complex building.
The models used for analyses were assumed fixed at elevation 85 feet. The modal
responses were combined in each direction using the square-root-of-the-the-sum-
of-the-squares method. Seismic forces in the east-west direction are resisted
primarily by the diaphragm slab at elevation 140 feet and by the shear walls along
column lines 5 and 17. The concrete shear walls run from grade to the diaphragm
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slab at elevation 140 feet and are 24 inches and 20 inches thick, respectively.
In addition to the shear walls, east-west lateral force-resisting elements are in
the form of a shear wall from grade to elevation 104 feet, with vertical X-bracing
running from elevation 104 feet to the elevation of the truss lower-chord bracing
system.
The interior framing supporting the floors at elevations 104, 119, and 140 feet is
supported on columns running from the foundation to the structural steel floor
framing at elevation 140 feet. These columns are framed to the floor beams and
girders with essentially simple connections and, consequently, are assumed to
offer no resistance to seismic forces.
Time-history analysis was used to generate floor response spectra. Response
spectra analyses were used to compute structural responses. The analysis in the
east-west direction was done using the SAP IV computer program.
A three dimensional model was necessary because the primary structural resisting
system and the mass of the building are unsymmetrical. The turbine pedestal was
not included in the east-west turbine building model because it is not attached to
the building at any other point other than the foundation. A north-south model
was generated and the modes and mode shapes and frequencies determined using the
TABS computer program. This information was used as input to the MATRAN computer
program to develop the acceleration time history at various floor elevations.
The vertical time-history analysis was performed. The model consisting of floor
beams, girders, columns and equipment weights was analyzed using the SAP IV
computer program.
With regard to the computer codes mentioned above we have requested that the
applicant provide verification for those codes which either have been modified bythe applicant or which are not generally accepted and verified codes in the public
domain.
As a result of the seismic analyses and evaluations, several major modifications
to the existing structural system were found to be necessary. Descriptions of
each of the more significant modifications are listed below:
(a) Modifications for East-West Forces
(1) Add exterior concrete buttresses from elevation 85 feet to 119 feet.
(2) Add an interior shear wall below elevation 119 feet along column line
11.
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(3) Strengthen floor diaphragms at elevation 104 feet and 119 feet.
(4) Add lower chord bracing in the roof trusses.
(5) Thicken shear walls on column lines 17 and 19 and install rock anchors.
(6) Add concrete pilasters to shear walls on column lines 5 and 31.
(7) Develop full strength of the vertical cross bracing member joints
between elevation 140 feet and the roof level along column lines 1 and
35.
(b) Modifications for North-South Forces
(1) Add shear walls along column lines A and B between elevation 104 feet
and 140 feet, and strengthen walls below elevation 104 feet.
(2) Add additional X-bracing above elevation 140 feet to roof along column
lines A and G.
(3) Strengthen connections of lower-chord roof bracing and vertical load
carrying trusses.
(4) Strengthen floor diaphragms at elevations 104 feet and 119 feet.
(5) Thicken shear walls on column lines A and G between 85 feet and 104 feet
and install rock anchors.
We will require more complete descriptions of these modifications and will provide
our evaluation of them in a future supplement to the Safety Evaluation Report.
In Amendment 56 the applicant accounted for the torsional eccentricities by
increasing the resulting stresses by 10 percent. At our request the applicant
performed an additional analysis to verify that the 10 percent increase in
stresses is more conservative than considering torsion in the models and applying
an accidental torsion as an equivalent assumed 5 percent eccentricity. Results of
this additional analysis showed that two of the walls were subjected to a stress
increase greater than 10 percent. The applicant is investigating whether any
remedial action is necessary for these walls. We will provide our evaluation of
this investigation in a future supplement to the Safety Evaluation Report.
In the original submittal (Amendment 50) the applicant determined that the two end
bays, namely No. 1 and 35 would be stressed beyond the yield point when a crane is
parked at the end of its travel (i.e., at one of the end bays). Later, the appli-
cant chose to impose administrative controls on movements of the cranes so that,
among other things, its location at any of the two bents would be prevented and
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thus the stresses exceeding the elastic range avoided until such time as a defini-
tive analysis of crane safety for a Hosgri event has been performed and it has
been reviewed and approved by the staff.
If, when this analysis is submitted, the applicant claims credit for structural
ductility we will review the justification and will ensure that the amount of
yielding is kept within the limits stipulated by the structural specification.
General aspects of analyses for all cranes and the administrative controls are
discussed in Section 3.8.5.4.8 below.
At our request, the applicant has performed an analysis to assess whether there is
enough clearance between the turbine pedestal and the adjacent structural elements
for a Hosgri event to prevent pounding. The analysis indicated that a larger
clearance was necessary. The applicant will be required to take necessary
remedial actions. The applicant intends to do this by removing concrete to
enlarge the gap. We will review this modification and provide our evaluation in a
future supplement to the Safety Evaluation Report.
Some of the information that we requested during the meetings the week of January 16,
1978 was not reviewed at that time, either because the information was not available
or because there was not enough time to review it before the meetings were concluded.
Subsequently, the applicant provided the information but, for many of the items,
we have not yet completed our review. Items in this category are as follows:
(1) A torsional analysis using assumed eccentricity.
(2) An investigation of the crane trolley vertical movement to assess the need
for vertical restraints.
(3) Computations on ductility requirements for nonlinear members.
(4) Results of analysis for the overhead crane.
(5) Foundation mat analysis and design.
(6) An assessment of the adequacy of turbine pedestal for Hosgri earthquake asrelated to the structural interaction and its effect on safety-related equipment.
(7) Horizontal and vertical mathematical models and their descriptions.
(8) Typical examples for horizontal and vertical smoothed response spectra.
(9) The mathematical model used for overhead crane analysis.
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(10) Information about the composition of the time history and base line
corrections.
The items listed below remain outstanding in our review of the turbine building
and require resolution. We will provide our evaluation of these matters in a
future supplement to the safety evaluation report:
(1) Verification and justification of computer codes (discussed above).
(2) An investigation of whether or not corrective action is necessary as a result
of torsion studies (discussed above).
(3) Further information regarding the end bents (discussed above).
(4) More detailed descriptions of the turbine building modifications (discussed
above).
(5) A description of the modification to enlarge the gap between the turbine
pedestal and adjacent structural elements (discussed above).
(6) An evaluation of several items that have been provided by the applicant but
which we have not yet reviewed (discussed above).
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3.8.5.4.6 Buried Pipes
The buried diesel fuel oil pipes connect the fuel oil tanks to the diesel
generator systems inside the turbine building. The buried auxiliary saltwater
pipes are anchored to the circulating water intake conduits at 40 foot intervals.
In order to assure the structural integrity of the conduits during earthquake
motions, they were reviewed for the same criteria as the auxiliary saltwater
piping and the diesel fuel oil piping.
The portion of a buried pipe far from the ends, and free of any external support
other than the surrounding soil, was assumed to move with the ground under the
propagation of seismic shear and compressional waves. With this assumption the
stresses in the pipe were computed as the products of soil strains and the modulus
of elasticity of the pipe material.
For the circulating water conduits, the concrete was assumed to crack and the
rebars were assumed to carry the entire tension load.
The method and criteria employed in the seismic evaluation of the buried piping
are based on the approach given in Section 6 of Bechtel Topical Report BC-TOP-4A,
(Reference 6, Appendix D to this supplement).
The axial and bending stresses due to propagation of a shear wave were calculated
in the following manner:
(1) The stresses of the pipe due to the horizontal motion were combined with the
stresses in the same direction due to the vertical seismic component, which
was assumed equal to two-thirds of the horizontal component, by the
square-root-of-the-sum-of-the-squares method.
(2) The resulting stress was added to the stress due to the internal pressure.
The maximum stresses induced in the auxiliary salt water and diesel fuel oil
piping were calculated as 20,000 and 36,000 pounds per square inch, respectively.
The maximum stress in the circulating water conduit reinforcing steel was deter-
mined as 28,000 pounds per square inch. These maximum stresses were in all cases
less than or equal to the specified minimum yield strengths for the material of
construction of 36,000 pounds per square inch.
Isolation sleeves or flexible couplings are used where the pipes enter the build-
ings to accommodate relative displacement between the soil and the buildings.
Based on these considerations we have concluded that the qualification of this
buried piping for the Hosgri event is acceptable.
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3.8.5.4.7 Outdoor Tanks
The applicant has reevaluated two types of outdoor tanks, namely, the outdoor
water storage tanks which are resting on the ground and the fuel oil tanks which
are buried in the ground.
The outdoor water storage tanks are cylindrical structures originally fabricated
of welded steel plates and anchored to a concrete foundation. The tanks consist
of a dome with a radius of 40 feet and a cylinder of 40 foot diameter and 52.5
feet in height.
For the analysis of the water storage tanks the free field Blume and Newmark
horizontal response spectra at four percent critical damping were used.
The criteria employed in the seismic evaluation of the outdoor water storage tanks
for the Hosgri event were similar to those for the major structures reported in
the previous sections of this supplement. A lumped mass-spring model fixed at the
base was initially used for analysis. We did not accept that analysis because the
tanks had not been analyzed as a thin shell, which would include ovaling effects
in the tank walls. At our request the applicant has performed another analysis
using an axisymmetrical finite element model for the stress analysis. The hydro-
dynamic pressure exerted in the tank wall was determined following the procedures
recommended in Veletsos and Yang, 1976 (Reference 7 of Appendix D to this supplement).
The paper suggested the procedures for computing the hydrodynamic effects in rigid
tanks in terms of impulsive and convective pressures. The applicant also compared
the results from this approach with those obtained by the approach described in
Chapter 6 of the Atomic Energy Commission publication TID 7024 (Reference 8,
Appendix D to this supplement).
The applicant has decided to add concrete shells, typically 8 inches thick, surround-
ing the steel tanks. Among other things this will strengthen the tanks against
ovaling.
There are two fuel oil tanks buried approximately 7 feet below the ground surface.
These tanks are 10 feet in diameter and 36 feet long. They are resting on compacted
soil.
For the analysis of fuel oil tanks, the applicant has used the free field Newmark
horizontal response spectra at 5 percent of critical damping and the corresponding
time-history acceleration coupled with deconvolution analysis to generate the
inputs to the finite element model.
A finite element analysis was performed for the fuel oil tanks using the FLUSH
program. This program is based on the vertical shear wave propagation theory and
has been used in many seismic analyses and discussed in the literature. The
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applicant indicated that the results computed by this program were more conserva-
tive than those based on the approach suggested by Newmark, 1968 (Reference 9,
Appendix D to this supplement).
Based on the analyses described above, the applicant has indicated that there
would be no overstress in the seismic Category I tanks. We are still reviewing
the analyses, and we will provide our evaluation of these matters in a future
supplement to the Safety Evaluation Report.
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3.8.5.4.8 Cranes
Several cranes in the plant could have adverse effects on safety-related equipment
if an earthquake should cause the cranes to fail in certain circumstances. These
cranes are:
(1) The polar gantry crane in the containment structure.
(2) The manipulator crane in the containment structure.
(3) The cask handling crane in the fuel building.
(4) The spent fuel bridge crane in the fuel building.
(5) The two turbine building cranes.
(6) The intake structure gantry crane.
The cranes have either not yet been analyzed for the Hosgri event or we have not
yet reviewed the analyses.
The applicant has agreed to provide analyses of the cranes combined with
appropriate operating restrictions to ensure that postulated crane failures due to
an earthquake would not affect plant safety. For example, the applicant intends
to demonstrate, in the near future, that the 125-ton-capacity cask handling crane,
in any crane position, can safely withstand the Hosgri event while carrying a
small load (about 1 ton). Operation of the crane would then be allowed in any
crane position but with only the small load until such time as the applicant had
demonstrated to our satisfaction that some less restricted mode of operation had
no effect on plant safety. This general approach is acceptable to us.
We will review the applicant's crane safety analyses and provide our evaluation in
a future supplement to the Safety Evaluation Report. We will include appropriate
restrictions in the technical specifications, to ensure that the cranes remain in
conditions that have been shown to be safe.
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3.8.5.4.9 Conclusions
As described in Sections 3.8.5.2 and 3.8.5.3 of this supplement we have found the
applicant's basic criteria (ground response spectra) and general methods of analysis
acceptable.
Subsections 3.8.5.4.1 through 3.8.5.4.8 above describe our review of the applicant's
structural analysis methods for the various structures, outdoor tanks, buried
piping and cranes.
Our review of the buried piping analyses is completed and we have found them
acceptable and, therefore, conclude that the qualification of buried piping for
the Hosgri event is acceptable (Subsection 3.8.5.4.6).
Our review of the auxiliary building analyses is nearly completed with three
specific items that require resolution (Subsection 3.8.5.4.3).
We have performed a substantial amount of our review for the containment shell,
the containment interior structures and the intake structure and have identified
13 specific areas that require resolution for these three structures (Subsections
3.8.5.4.1, 3.8.5.4.2 and 3.8.5.4.4).
The applicant has performed analyses of the outdoor tanks in accordance with the
general methods and criteria that we requested but we have not yet completed our
review of the analyses (subsection 3.8.5.4.7).
For cranes, the applicant will employ a combination of analysis and administrative
controls to ensure plant safety. This general approach is acceptable. We have
discussed possible approaches with the applicant and believe that this approach is
feasible. However, we have not yet reviewed the specific proposals (subsection
3.8.5.4.8).
For the turbine building, the major part of our review has not yet been completed.
In our review to date we have identified four specific areas that require resolution:
verification of computer codes, investigation of the results of torsion studies,
further information regarding the end bents (if needed depending on administrative
controls for cranes) and further information related to the modifications to the
turbine pedestal gap. However, there are a number of items for which we have
requested additional information. The applicant has recently submitted additional
information but we have not yet completed our review of it. In addition, we will
need more detailed descriptions of the turbine building modifications for our
review (Subsection 3.8.5.4.5).
Overall, the major part of our review of the applicant's reevaluation is completed
and we can conclude that (1) we have a reasonably clear assessment of the pertinent
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structures' capabilities with respect to the Hosgri event and (2) we have identified
the remaining matters that require acceptable resolution. Accordingly, provided
that the outstanding matters described above are resolved in a conservative manner,
we will be able to conclude that the applicant's structural analyses are acceptable.
We will continue our review of the outstanding matters discussed above and provide
our conclusions in a future supplement to the Safety Evaluation Report.
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3.9 Mechanical Systems and Components
3.9.3 Seismic Reevaluation
This section discusses our review to date of the applicant's seismic reevaluation
of mechanical systems and equipment and it summarizes the outstanding issues that
require resolution.
3.9.3.1 Summary of Staff Review
The applicant has performed a seismic reevaluation of the plant's mechanical
systems and equipment.
In June 1977, the applicant submitted the results of a significant portion of the
seismic reevaluation in Amendment 50 to the operating license application. This
information has subsequently been supplemented by Amendments 53, 56, 59 and 60.
We reviewed Amendments 50 and 53 and requested numerous items of additional infor-
mation. The applicant responded to these requests in Amendment 56 in November
1977 and in several letters.
We reviewed the applicant's responses and then held seismic design criteria imple-
mentation meetings. The meetings concerning the applicant's scope of work (balance-
of-plant) were held in the applicant's offices the week of January 23, 1978. The
meetings concerning the Westinghouse scope of work (nuclear steam supply system)
were held in Pittsburgh, Pennsylvania the week of January 30, 1978.
At these meetings we selectively reviewed the implementation of the seismic design
criteria for the plant. We also pursued questions regarding the applicant's
previous responses. The results were documented in our summary of the meetings
which included a lengthy list of areas where further information would be required.
To follow this up we had several conversations and informal meetings with the
applicant, primarily during the weeks of March 6, 1978 and March 13, 1978. Theapplicant responded to questions that had been raised during the seismic design
criteria implementation review meetings. As discussed in Section 1.0 of this
supplement, the voluminous detailed technical information that the applicant
provided informally during these follow up meetings and discussions has been
documented in our files and made available in the public document rooms.
The results of our review and the items that remain outstanding are described in
the following sections of this supplement.
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3.9.3.2 General Methods of Analysis
Description of Methods
The methods used in the Hosgri event reevaluation of mechanical equipment and
systems are given in Amendment 50 and subsequent amendments to the operating
license application and are summarized below.
Floor response spectra were utilized as described in Section 3.9.3.3 below.
The methods used in the reevaluation were generally the same as used in the original
analysis with the exception of the items listed below. (Listing the differences
from the original methods is a way of describing the general analysis methods.
Our evaluation basis is, however, the conservatism of the methods rather than
comparison with the original methods.)
(1) Damping values recommended in Regulatory Guide 1.61 were generally used in
the reevaluation. A damping value of 4 percent was used for the reactor
coolant system as opposed to 3 percent in the Regulatory Guide.
The damping values which were used in the original analysis for double design
earthquake are below the values currently recommended in Regulatory Guide
1.61 and would give higher calculated responses.
The damping values recommended by Regulatory Guide 1.61 constitute our current
criteria and have been acceptable on all applications for several years.
Therefore, they are acceptable for use in the seismic reevaluation.
The value of 4 percent for the reactor coolant system was justified in actual
plant tests by Westinghouse Electric Corporation and has been accepted in our
review of other plants. The results were reported ir Westinghouse Topical
Report, WCAP 7921-AR, "Damping Values of Nuclear Power Plant Components",
submitted in August 1973. After reviewing the topical report we approved the
4 percent value for use in similar Westinghouse reactor coolant systems
provided that similarity to the system tested is demonstrated. Our evaluation
was presented in a letter to Westinghouse dated May 16, 1974. We will require
that the applicant demonstrate similarity and we will provide our evaluation
of this item in a future supplement to the Safety Evaluation Report.
For the reasons discussed above, the damping values used in the seismic
reevaluation for mechanical equipment and systems are acceptable, subject to
satisfactory demonstration of the reactor coolant system's similarity to the
system that was tested.
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(2) In some cases, where material test data were available, actual material
properties were used in lieu of code specified minimum properties to
establish allowable stress limits to justify structural integrity where the
calculated stress exceeded the limits of The American Society of Mechanical
Engineers Boiler and Pressure Vessel Code (ASME Code). Code allowable values
were used in the original analysis.
Allowable stress values were established using the bases prescribed by
Appendix III of Section III of the ASME Code so that the factors of safety
used in the code are preserved. For this reason, we consider the use of
actual material properties acceptable for the reevaluation.
(3) The responses to Hosgri earthquake loads or the double design earthquake
loads (whichever was more limiting) were combined with the response due to
normal operation and the response due to postulated loss-of-coolant-accident
loads using the absolute summation method for response combination.
This is a conservative procedure which results in the reactor coolant system
being designed for loads well in excess of those calculated for a seismic
event alone without a pipe break. Even though the assumed seismic event is
not expected to cause a pipe break in a seismically designed piping system,,
these loads are combined for design purposes to produce extra margin. A
further conservative element is the requirement that the peak responses to
these loads be combined on an absolute sum basis. This approach used by the
applicant is conservative and, therefore, acceptable.
(4) A one-quarter scale model structural test was performed on the reactor vessel
shoe and pad system to determine the load-carrying capacity of the assembly
rather than using the usual methods to determine code allowable stresses.
The allowable load was limited to 80 percent of the ultimate load obtained
from the test. This follows the practice permitted by Appendices II and F of
Section III of the ASME Code and is, therefore, acceptable.
(5) In the reevaluation, upon the applicant's own initiative, low amplitude shock
or vibration testing of systems and components as they are actually installed
(in-situ testing) has been performed to experimentally validate the natural
frequencies, mode shapes and damping values used in seismic analysis. This
was done for selected components and supports such as tanks, heat exchangers,
valves, piping systems and supports. Where significant differences were
found, the analyses were revised to correspond to knowledge gained in the
tests.
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This procedure is not usually required. It represents an improvement in the
accuracy of the seismic design methods. It has not resulted in any relaxation
of requirements. It has, in a few instances, indicated a need for refinement
of the analysis procedures and in very few instances required further strength-
ening of the supports. Therefore, we have found it acceptable.
(6) At our request the applicant performed a special study, not usually required,
in which many piping systems, including the reactor coolant loops, were
analyzed assuming single snubber failures. We are still reviewing this study
as discussed further in Section 3.9.3.6 below.
As a general method, however, this study represents an improvement in the
accuracy of our knowledge of the plant's seismic capabilities and is, therefore,
acceptable.
Evaluation of Methods
Several conservatisms are inherent in the usual procedures for the seismic design
of nuclear power plant mechanical systems and components. They have been extensively
discussed in various forums. The general methods used by the applicant in this
reevaluation as described above contain few variations from the usual procedures
as defined by our usual criteria. One is the higher damping value allowed for the
reactor coolant loop analysis. As discussed above, this is based on tests and is
normally acceptable for Westinghouse reactor coolant systems provided that simi-
larity with the system that was tested is demonstrated. Another is the use of
actual material test strengths. As discussed above, the code safety factors have
been retained in using these material test data to establish allowable stress
levels. Finally, the in situ testing program and the piping snubber study represent
improvements, relative to the normal case, in our knowledge of the plant's seismic
capabilities.
In our review we have found that in the individual steps where there are variations
from the usual procedures, those individual steps have remained conservative and
have retained adequate safety margins. In the remainder of the analysis, the
usual conservative elements apply. Accordingly, based on our review, we have
concluded that the general methods of analysis described above are conservative
and provide for adequate safety margins in the design of Category I mechanical
systems and components. We therefore find them acceptable, subject to satisfactory
demonstration of the similarity of the Diablo Canyon reactor coolant system to the
reactor coolant system that was tested to justify the use of four percent damping.
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3.9.3.3 Floor Response Spectra
Floor response spectra characterize the seismic inputs to mechanical systems and
equipment at various points in the structures. They were developed in the
structural analysis as discussed in Section 3.8 of this supplement.
We have reviewed the methods used by the applicant to obtain from the floor
response spectra the appropriate response spectra to be used in the analysis of
particular piping systems and components. The floor response spectra generated
from the Blume and Newmark ground motion inputs were enveloped to obtain the
actual floor response spectra used in the analyses. The spectral accelerations
were obtained from the enveloped rotational floor response spectra added to the
accelerations from the enveloped horizontal floor response spectra.
As required by the routing of a piping system, linear interpolation was used to
generate the spectra for supports or anchors located between floors. The
different response spectra at the corresponding support or anchor elevations were
then enveloped to obtain the appropriate response spectra for the analysis. At
the criteria implementation review meetings we reviewed these procedures as used
in actual problems. They were found to be consistent with the procedures
delineated in Amendment 50 and subsequent amendments to the operating license
application.
These methods constitute a conservative manner of utilizing the calculated floor
motions for the design of mechanical systems and components. Therefore, based on
our review, we conclude that the methods are acceptable.
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3.9.3.4 Piping System Analysis
This section discusses our evaluation of the applicant's methods for piping system
modeling, analysis, response combination, load combination and stress evaluation.
The applicant's methods and the outstanding items in our review are described in
subsections 3.9.3.4.1 through 3.9.3.4.5. Our conclusions are presented in
subsection 3.9.3.4.6.
3.9.3.4.1 Response Combinations
The response spectrum modal superposition method used by the applicant to combine
the responses from horizontal and vertical earthquake components was the method
developed and in general use before the first issuance of Regulatory Guide 1.92,
"Combining Modal Responses and Spatial Components in Seismic Response Analysis,"
December 1974. The method used by the applicant provides for absolute summation
of the response due to one horizontal component of excitation and the response due
to the vertical component of excitation for each piping system frequency. All
modal responses at various frequencies were then combined by the square-root-of-the-
sum-of-the-squares rule to obtain the total response. This process was then
repeated for the other horizontal component and the vertical earthquake component
and the controlling value selected for design.
One of the procedures contained in Regulatory Guide 1.92 (Regulatory Guide 1.92
method) consists generally of adding responses due to the two horizontal components
of excitation and the one vertical component of excitation by the square-root-of-
the-sum-of-the-squares rule for each mode (frequency), calculating each of the
three-components independently. Responses for the various modes are then combined
by the square-root-of-the-sum-of-the-squares rule to obtain the total response.
Appropriate adjustments are made for modes that are closely spaced in frequency.
The applicant's method and the Regulatory Guide 1.92 method contain different
types of conservative elements. The applicant's method consists of using the
absolute sum of the responses to a horizontal excitation and a vertical excitation.
The Regulatory Guide 1.92 method consists of combining the responses to both
horizontal components and the vertical component at the same time. As a result of
the different approaches the Regulatory Guide 1.92 method gives more conservative
results in some locations but the applicant's method gives more conservative
results in other locations. Thus, neither method is universally more conservative
than the other.
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Since the Regulatory Guide 1.92 method does give greater loads at some locationsand it is the method prescribed for newer plants, it provides a basis for
comparison. Accordingly, we have requested that the applicant perform several
sensitivity studies to assess the possible effects of such increased loads. Thestudies will provide more detailed information which we will need to reach a
conclusion regarding the safety significance, if any, of this matter for the
Diablo Canyon plant.
Some of the studies have been completed and others are in progress. They are
discussed in further detail in the following sections of this supplement. We willreview the results of the studies and provide our evaluation of them in a future
supplement to the Safety Evaluation Report.
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3.9.3.4.2 Reactor Coolant System Main LooDs
In Section 5.2.1 Supplement No. 4 and Supplement No. 5 to the Safety Evaluation
Report, we discussed asymmetric loads from a postulated loss-of-coolant accident.
Since loss-of-coolant accident loads are combined with seismic loads in reactor
coolant system design, and in light of the high seismic loads for this plant, we
have required that the asymmetric load issue be resolved along with the seismic
reevaluation. Our evaluation of both matters is presented below.
The subcompartment pressure calculations used to predict loads due to buildup of
steam pressure in containment subcompartments have been found acceptable as
discussed in Section 6.2.1 of this supplement.
The effect of the combined loads on the reactor fuel remains an outstanding issue
as discussed in Section 6.3.3 of this supplement.
The applicant employed the Westinghouse analytical code, MULTIFLEX, to evaluate
the hydraulic transients within the entire reactor coolant system. This model was
documented in the Westinghouse Topical Report WCAP 8707-P/A, "MULTIFLEX, A
Fortran-IV Computer Program for Analyzing Thermal-Hydraulic-Structure Dynamics,"
Volumes I & II September 1977. Our evaluation was provided in a letter to
Westinghouse dated June 17, 1977. We approved use of this model contingent upon
the inclusion of certain code modifications to be done on a plant-by-plant basis
whenever MULTIFLEX is used. Since the appropriate plant specific requirements
have all been included in the Diablo Canyon analysis, this approach is acceptable.
The applicant has performed detailed structural analyses for the reactor coolant
system for the loads induced by a loss-of-coolant accident resulting from
postulated pipe ruptures. Included in the analyses were postulated pipe breaks
that produced the most limiting loads on (1) the reactor coolant piping systems
including nozzles, (2) the reactor vessel, vessel internals and vessel supports,
(3) the steam generators and supports, (4) the pressurizer and supports, and (5)
the reactor coolant pumps and supports. The analyses included the effect of
modifications to the plant which reduce the severity of the postulated reactor
vessel nozzle break by the addition of pipe displacement restraints in each
primary shield wall pipe annulus.
All loads acting on the system were included in the analyses. Among these are
reaction loads from the pipe rupture, asymmetric loads due to decompression waves
acting on the reactor internals (for the reactor vessel nozzle break) and the
external asymmetric subcompartment pressure loads. The dynamic model for seismic
analysis of the reactor coolant system included the four reactor coolant loops,
their respective steam generators and reactor coolant pumps and their supports,
the reactor vessel and supports, and the reactor vessel internals. The influence
of the main steam lines was included by applying the effective stiffness at each
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of the four steam nozzles. The response spectrum model superposition method was used
for the analysis. Hosgri response spectra and a damping value of 4 percent were used
in the evaluations.
The reactor coolant loops (unbroken portions) were analyzed for the combined loads.
The loads on the components such as the piping, the reactor pressure vessel including
its internals and the control rod drive mechanisms, the reactor coolant pumps and the
steam generators and their supports were evaluated and the resulting stresses found to
be acceptable. The effect of these loads on the reactor fuel remains outstanding as
discussed in Section 6.3.3 of this supplement.
In performing these analyses the applicant evaluated the adequacy of the Diablo
Canyon reactor coolant system considering several load combination assumptions as
listed below:
(1) The seismic event occurring alone (Normal + Seismic);
(2) The loss-of-coolant accident occurring alone (Normal + LOCA); -
(3) The seismic event and loss-of-coolant accident occurring simultaneously
with the peak loads combined by the square-root-of-the-sum-of-the-squares rule
(Normal + [(Seismic)2 + (LOCA) 2] 11 2 ).(4) The seismic and loss-of-coolant accident events occurring simultaneously
with the peak loads combined by absolute summation (Normal + Seismic +
LOCA);
At our request, as indicated by item (4) above, this included absolute summation
of normal loads, peak seismic loads (whichever was more limiting between the
double design earthquake loads and the Hosgri event loads) and peak pipe break
loads. This was.the most conservative of the load combinations considered. The
applicant's evaluation of the effects of the most conservative combination indicated
that all components and supports of the primary coolant system are capable of
withstanding the effects of the simultaneous occurrence of normal operating loads,
peak seismic loads and peak loads from a postulated loss-of-coolant accident.
The outstanding items in our review of the applicant's evaluation are described below.
As a general rule, many different time history motions can be developed that will cor-
respond to a given response spectrum. Thus, one of many different time history motions
could be used as the seismic input for the design of a particular component. The dif-
ferent time histories that could be used would yield somewhat different calculated re-
sponses for a linear elastic system. This is considered acceptable.
However, mechanical components with gaps (parts of the reactor internals and the
control rod drive mechanisms) are believed to be more sensitive to selection of thetime history motion than the usual linear components. That is, non-linear components
will yield more widely variable calculated responses, depending on the time history
motion selected for use in design.
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At the meetings during the week of January 16, 1978, we discussed this question
with the applicant but the matter was not satisfactorily resolved. We will
require that the applicant provide further information regarding the sensitivity
of non-linear components to selection of the time history motions used in design
and the significance of the motions that were selected. We will provide our
evaluation of this matter in a future supplement to the Safety Evaluation Report.
The conclusions in the applicant's evaluation of the reactor coolant system
combined load analysis are based upon the acceptability of the method for treating
the combination of seismic modal responses and spatial components used by the
applicant, which is different from the method contained in Regulatory Guide 1.92.
The applicant is completing a study of the primary system in which an assessment
will be made of the stresses for the limiting load combination discussed above,
with the peak seismic stresses determined through the Regulatory Guide 1.92
method. Preliminary results indicate that the stresses which result will be
acceptable. We will review the applicant's study and provide our evaluation of
this matter in a future supplement to the Safety Evaluation Report.
The reactor coolant system combined load analyses submitted by the applicant are
stated to apply to Diablo Canyon Unit 1. We will require that the applicant
address whether or not there would be any differences for Unit 2 and, if so, what
the differences are and whether they have any significance. We will provide our
evaluation of this matter in a future supplement to the Safety Evaluation Report.
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3.9'3.4.3 Reactor Coolant System Branch Piping
This section discusses branch piping connected to the reactor coolant system main
loops. The piping under discussion runs from the reactor coolant loops to the
first piping anchor since the branch piping must be analyzed to the first anchor.
It often extends beyond the reactor coolant system boundary, which is defined by
isolation valves rather than piping anchors.
The reactor coolant loop branch piping was examined for the faulted condition
loading combination using the Hosgri event and a postulated loss-of-coolant accident
occurring simultaneously with the peak loads combined by absolute summation.
Dynamic time history analyses were performed for five branch lines including the
pressurizer surge line. The systems chosen have dynamic restraints close to the
loop connection and therefore are likely to be the most highly stressed branch
lines.
The seismic analyses were performed using the analysis method the applicant has
been using for all the piping systems. The results of the combined Hosgri plus
loss-of-coolant accident analysis indicated that the piping stresses were well
within the allowables and the supports would be adequate for the combined loads.
Based upon the margin that has been demonstrated, the piping stresses would not be
expected to increase above allowable levels if the Regulatory Guide 1.92 method
for combining responses were used rather than the applicant's method. With respect
to support loads, in order to reach a conclusion on the significance of the Regula-
tory Guide 1.92 method, we have requested that the applicant provide, for our
review, support capacities based upon faulted condition allowable stresses. We
will review the information and provide our evaluation of this matter in a future
supplement to the Safety Evaluation Report.
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3..9.3.4.4 Other Piping
This section discusses piping outside the scope of the reactor coolant system main
loops and branch piping.
Support Stiffness
The applicant had assumed rigid piping system supports rather than modeling the
actual stiffness of the supports. Modeling the actual stiffness should provide
more accurate results. We requested a sensitivity study to verify the
acceptability of the rigid support assumption. This study consisted of performing
Hosgri event seismic analyses of several representative piping systems using
actual support stiffnesses. The results indicated that both the piping stresses
and support loads increased at some locations and decreased at other locations.
There were no cases where the increased piping stresses exceeded the allowable
stresses. As discussed below, the increased support loads were also found
acceptable.
With regard to piping supports, the applicant has evaluated all the piping and
supports for spectra associated with the design earthquake, the double design
earthquake and the Hosgri event. Many systems were evaluated twice for the Hosgri
event, first using estimated spectra and then again using the final calculated
spectra. During the Hosgri event evaluation supports were added to control the
piping for the greater earthquake input. The addition of these supports resulted
in a redistribution of loading during the Hosgri event. The resulting effect was
an overall reduction in seismic loading for certain supports that had been
previously qualified and installed to withstand higher seismic loads. All the
supports which had increased loads in this study were qualified for these loads by
either qualification for the increased load from a previous analysis, support
member stress analysis or by a comparison with the ultimate load capacities from
the support manufacturer. The acceptability of the supports for all the increased
loads that were obtained in the sensitivity study has been demonstrated.
Thus, this sensitivity study has demonstrated that the effect of modeling actual
support stiffness, in the typical systems studied, would not result in piping
stresses exceeding allowable values or support loads exceeding support capacities.
Seismic Anchor Movements
The applicant did not initially account for the loads due to relative motion
between piping anchors resulting from differing seismic motions of the structures
at the different anchor locations (seismic anchor movements). In the applicant's
judgment sufficient margin to accommodate seismic anchor motion stresses was
available between the thermal expansion stresses and the secondary stress
allowables.
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At our request the piping systems which would experience the largest seismic anchor
motions were analyzed. This consisted of eight piping lines. The applicant used
Hosgri event seismic anchor displacements, although current code rules require only
an evaluation for anchor displacements caused by an operating basis earthquake (for
this plant the design earthquake). The Hosgri event anchor movements are more limit-
ing than those which would be obtained by using the design earthquake. With the in-
clusion of the stresses from the Hosgri seismic anchor movements, the total piping
stresses in these eight lines were still conservatively within the allowable stresses
specified in the appropriate piping cc-des.
With regard to pipe support stresses due to seismic anchor movements we requested
that, where the support loads would clearly produce primary stresses in the supports,
such as supports consisting of a member in pure tension, the Hosgri event seismic
anchor movement loads be included in the faulted plant condition load combination.
This is a more conservative approach than is required by current code rules. Using
faulted condition allowable stresses such supports were found to be acceptable with
seismic anchor movement loads included. The evaluations required by the current code
rules were also performed and the resulting stresses were determined to be acceptable.
Response Combinations
In order to' assess the significance of the Regulatory Guide 1.92 method of combining
responses, we requested that the applicant perform a sensitivity study using normal
operating loads combined with Hosgri event loads.
One study has been completed. For the systems studied there were both increases
and decreases in piping stresses and support loads. The piping stresses remained
within the allowable stresses and the supports were found acceptable for the
resulting loads. However, this study did not account for the effects of closely
spaced modes, which is one of the elements of the Regulatory Guide 1.92 method.
Accordingly, we requested an additional study that would include consideration of clo-
sely spaced modes as recommended by the Guide. We will review this additional study
and provide our evaluation in a future supplement to the Safety Evaluation Report.
Combined Effects
In order to make conclusions on the significance of the combined effects of the
three matters discussed above, we have requested that the applicant perform an
additional sensitivity study. This study will assess the effect of using actual
support stiffnesses along with the effect of using the Regulatory Guide 1.92
method of combining responses. It will also include piping with relatively high
seismic anchor movements. We will review this study and provide our evaluation in
a future supplement to the Safety Evaluation Report.
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3.9.3.4.5 Simplified Analyses
Cold piping with diameters between two and five inches and both cold and hotpiping of two inches diameter or less were designed using simplified methods;
i.e., restraint spacing criteria developed by the applicant. For this purpose
cold piping is defined as piping with design temperatures less than about 200
degrees Fahrenheit for carbon steel and about 165 degrees Fahrenheit for stainless
steel. This method of design is common practice. Using simplified dynamic
analyses of a pipe segment modeled as a simply supported beam, restraint loading
and spacing rules are developed to ensure satisfactory performance for various
types of smaller piping. Restraints are then installed according to these rules.
For the Hosgri event, in order to evaluate the.adequacy of the piping and supports
designed in this manner, we requested the applicant to analyze several of these
piping systems using the response spectrum modal superposition methods that are
used for larger piping. The applicant performed several analyses for actual
systems where supports had been positioned by use of the spacing criteria. Actual
support stiffnesses were used. The results indicated that the pipe and support
stresses were within allowable values.
The spacing criteria method is commonly used, is based on conservative
calculations, and the more detailed analyses have indicated satisfactory results
for the systems that were checked. Therefore, we have concluded that this is a
reasonable and acceptable basis for the design of the piping and supports for
which this method was used.
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3.9.3.4.6 Conclusions
As described above we have reviewed the applicant's methods for piping system
modeling, analysis, response combination, load combination and stress evaluation.
The outstanding items that have resulted from our review and require resolution
are described in Sections 3.9.3.4.1 through 3.9.3.4.5 above and are summarized in
Section 3.9.3.9 below.
Subject to satisfactory resolution of the outstanding items described above, we
have found the following in our review:
(1) The applicant's modeling techniques will lead to accurate representation of
the piping systems.
(2) The applicant's analysis techniques including combination of responses will
characterize the total response of the piping systems in a manner for design
purposes.
(3) The applicant used loading combinations for normal operation, anticipated
transients and postulated events equivalent to normal, upset, emergency and
faulted condition load combinations which are in conformance with our current
criteria which are conservative.
(4) The stress limits used for the plant piping and supports were based upon or
equivalent to current ASME Code stress limits in conformance with our current
criteria which are conservative.
Accordingly, based on our review, we have concluded that, subject to satisfactory
resolution of the outstanding items discussed above, the applicant's piping system
analysis methods are in conformance with accepted industry standards and our
current criteria and are conservative and, therefore, are acceptable.
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4.9.3.5 Seismic Category I Piping Boundaries
In the terminology used by the applicant, piping that was originally designed and
supported to withstand earthquake loading is called Design Class 1 piping. Piping
that was not originally designed and supported for earthquake loaaing is called
Design Class 2 piping. Thus, Design Class I corresponds to seismic Category I in
our usual terminology. We discussed boundaries between Design Class 1 piping and
Design Class 2 piping during the meetings the week of January 23, 1978.
As discussed in Section 3.2.1 of this supplement, we have reviewed the systems and
equipment needed to achieve long-term cold shutdown conditions following a Hosgri
event (cold shutdown review). In the cold shutdown review it was assumed that (1)
only qualified equipment would be available, (2) single failures may occur, and
(3) offsite power may be lost indefinitely. The applicant has demonstrated one
way of meeting this objective and has included the necessary systems and equipment
in the seismic reevaluation (to be qualified for the Hosgri event). Since this
cold shutdown review went beyond our normal criteria regarding what systems must
be designed for earthquakes, some of the piping sytems that the applicant relied
upon are Design Class 2.
As a result of our discussions during the meetings the week of January 23, 1978,
we will require that the applicant identify the boundaries between Design Class 1
systems and Design Class 2 systems within the piping systems that were relied upon
in the cold shutdown review. We will require that the supporting of the Design
Class 2 systems that were relied upon in the cold shutdown review be upgraded to
be equivalent to the supporting of Design Class I piping as necessary to ensure
that the Design Class 2 systems involved will perform their required cold shutdown
functions.
In a similar manner, we will also require that the supporting of any Design Class
2 piping systems that are connected to Design Class 1 piping systems or to Design
Class 2 systems that were relied upon for cold shutdown be upgraded as necessary
to ensure that the vital systems will perform their intended safety function.
We will review the applicant's provisions for accomplishing these objectives and
provide our evaluation in a future supplement to the Safety Evaluation Report.
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3.9.3.6 Piping Snubber Study
Piping snubbers are mechanical or hydraulic devices commonly employed in nuclear
power plant piping systems. Their function is to allow free pipe movement during
slow pipe motions such as thermal expansion but to lock and provide stiff
restraint against rapid pipe motions such as seismic loading or pipe break
loading. Piping systems stresses can be expected to increase beyond the values
calculated in design analyses if a pipe snubber should malfunction upon demand.
In our reviews we do not require that applicants assume such snubber malfunctions
or accommodate for them in the analysis. We do, however, require that snubbers be
periodically examined during the life of the plant for parameters which affect
their functioning.
For this plant, however, at our request, the applicant has prepared a study on the
probability and consequences of assumed single failures of snubbers. The study is
in two parts, snubbers for the reactor coolant loops and snubbers on other piping
systems. Both parts of this study considered failures to lock for a dynamic event
as well as rigid lockup against thermal expansion.
Reactor Coolant System Main Loop Study
The only snubbers in the reactor coolant main loops are the four snubbers on each
of the upper steam generator supports. For an assumed failure of one snubber to
lockup against rapid motion the applicant determined the resulting piping stresses
and support loads for two separate conditions - the Hosgri event and a main steam
line break. In addition, one of the four snubbers was postulated to be locked
during thermal expansion.
For the Hosgri event, lockup of one snubber did not result in overloading the
other snubbers. For the main steam line break analysis, the loading on one other
snubber was in excess of the catalog rated capacity but substantially within the
loading for which the snubber has been tested and designed. For the thermal
expansion analysis there is no effect on the other snubbers.
For all the conditions analyzed the piping stresses and other support member
stresses were within the allowable stresses specified by the appropriate piping or
structural codes.
We have concluded on the basis of this study that the reactor coolant system main
loops would not be significantly affected by a single failure of one of the steam
generator support snubbers.
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Study of Remainder of Piping Systems
The applicant used a probabilistic fracture mechanics approach to assess the
effects of assumed snubber failures on the remaining systems. The applicant has
estimated as a result of this portion of the study that the probability of a pipe
failure due to thermal expansion against a snubber lockup is approximately 2 x
10-4 per year and the probability of a pipe failure at Diablo Canyon due to a
snubber failing to lockup during the seismic event is approximately 10-7 per year.
An assumption upon which the applicant's conclusions are based is that the
remaining supports, when a snubber is failed in an earthquake analysis, are
capable of carrying the redistribution of loading. Since the validity of this
assumption has not been verified and since some of the probability and facture
mechanics aspects are still under review, our evaluation of this portion of the
study will be addressed in a future supplement to the Safety Evaluation Report.
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3.9.3.7 Seismic Qualification of Mechanical Components
The criteria for seismic qualification of mechanical equipment and the review by
the seismic qualification review team are the same as discussed in Section 3.10 of
this supplement for electrical equipment.
As also discussed in Section 3.10 of this supplement, where equipment is
requalified by testing, we will review the results of the requalification tests
when they are available and provide our evaluation in a future supplement to the
Safety Evaluation Report.
The applicant's qualification of mechanical components and supports for the Hosgri
event used a composite of analytical and experimental procedures.
For analytical procedures the loading conditions and associated stress criteria
used for the seismic evaluation of this equipment meet the appropriate current
design requirements of the ASME Code and are consistent with our recent staff
positions.
The applicant has used in-situ tests for selected typical components to confirm
that the frequencies, mode shapes and damping values used in the analysis were
proper. The applicant has submitted reports of in-situ testing results for diesel
engine generators and accessories, boric acid tanks, and component cooling water
heat exchangers. We have reviewed these three reports. We found that the natural
frequencies, mode shapes, and damping values used in the Hosgri reevaluation for
the diesel generators and the boric acid tanks were adequate compared to the test
results. However, the experimental natural frequencies and mode shapes of the
component cooling water heat exchangers disagreed with those used in the Hosgri
reevaluations. The applicant is revising the mathematical model in accordance
with the experimental parameters to determine the structural integrity of the
components and supports. In addition, in the Hosgri reevaluation of the boric
acid tanks, we found that the sloshing effects of the boric acid in the tanks were
not considered. The applicant is assessing these effects on the structural
integrity of the tank supports. Furthermore, the applicant is preparing the
reports for the rest of the in-situ tests and will submit the reports for our
review. We will provide our evaluation of these matters in a future supplement to
the Safety Evaluation Report.
For the items which received additional stiffening as a result of the reevaluation
program, insignificant effects resulted from changes in damping. This is true
because the stiffened equipment and supports have their natural frequencies in the
rigid range where the difference in acceleration due to different damping values
is very small.
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Where components were qualified by shake testing, the laboratory tests were
full-scale qualification tests.
As a result of concerns expressed by our seismic qualification review team, the
applicant has conducted seismic testing to qualify the steam generator safety
valves for the Hosgri event. We have reviewed the test methods and results. We
found that the testing was in conformance with the criteria discussed in Section
3.10 of this supplement and, therefore, acceptable.
The applicant has also committed to perform qualification testing for a 14 inch
motor operated valve. Valves of this model are used as isolation valves between
the reactor coolant system ard the discharge side of the residual heat removal
system (valves 8700A and 8700B). The applicant has indicated that this
qualification test will also be designed to represent the reactor coolant system
isolation valves on the suction side of the residual heat removal system (valves
8701 and 8702) which are different models. We have reviewed the proposed test
criteria and procedures and we found them generally in conformance with the
criteria discussed in Section 3.10 of this supplement and therefore, generally
acceptable. However, we are still reviewing the applicant's rationale for the
proposed test inputs to accomplish the test's objectives and we will require
further justification. This item remains outstanding. We will provide our
evaluation in a future supplement to the Safety Evaluation Report.
The applicant has submitted a report on the seismic qualification of Limitorque
valve activators. We are reviewing the report and its applicability to the
actuators used at the Diablo Canyon. In addition, the 14-inch motor operated
valve testing program described above will constitute part of the seismic
qualification for Limitorque valve actuators at Diablo Canyon. We will provide
our evaluation of the seismic qualification of Limitorque valve actuators at
Diablo Canyon in a future supplement to the Safety Evaluation Report.
At the meetings during the week of January 30, 1978, information concerning the
natural frequency of one valve (HCV 637) was not available for our review. In
addition, information was not available for our review concerning the seismic
qualification of several other valves for the Hosgri event (valves 8805 A/B, 8387
B/C, 8146, 8471, FCV 110A, PCV 455C, 9351 A/B, 8145, HCV 142 and 8107). We will
require that the information be submitted for our review. The results of our
evaluation will be provided in a future Supplement to the Safety Evalution Report.
For active valves that may be required to function durig the Hosgri seismic event
to mitigate the effects of system transients and/or accidents, functional
operability must be assured during the earthquake. The applicant qualified the
active valves by assuring the functional operability after the earthquake but did
not evaluate the operability during the seismic event. The valves involved
include at least those active valves listed in Table 7-7 of the Amendment 50 to
3-66
the operating license application. We will require that functional operability be
assured for active valves during the seismic event. We will report the resolution
of this matter in a future supplement to the Safety Evaluation Report.
At the meetings during the weeks of January 23 and January 30, 1978 and in
subsequent informal meetings we found that the information in Tables 7-5 through
7-8 of Amendment 50 to the operating license application was either incomplete or
inconsistent with the informal information we have received. We will require that
the applicant update these tables in an amendment to the operating license
application and we will provide our evaluation in a future supplement to the
Safety Evaluation Report.
As described above, We have reviewed the applicant's program for seismic
qualification of mechanical equipment. The outstanding items that resulted from
this review and require resolution are described above and summarized in Section
3.9.3.9 below.
Subject to satisfactory resolution of the outstanding items discussed above, wehave found in our review that the applicant's program for seismic qualification of
mechanical equipment by analysis and testing conforms with the criteria.discussed
in Section 3.10 of this supplement. Since these criteria provide reasonable
assurance that safety related equipment will function as intended during and after
a Hosgri event, we have concluded, based on our review and subject to satisfactory
resolution of the outstanding items discussed above, that the applicant's program
for seismic qualification of mechanical equipment is acceptable.
3-67
3.9.3.8 Design Interfaces
We reviewed the area of interfaces between the applicant and their contractors,
Westinghouse and various vendors, at the meetings during the week of January 16,
1978 and the week of January 30, 1978. Documents such as contractor performed
analyses were examined to determine if the analysis methods used by the
contractors were consistent with those used or required by the applicant's
engineering staff. Other documents were reviewed to ascertain whether information
such as valve accelerations determined by piping analysis were transmitted to and
used for equipment qualification. Several analyses were reviewed to ver;fy that
loads such as equipment nozzle loads were being transmitted to the vendors for
acceptability or compared with allowables provided by the vendors. Portions of
these meetings were also spent reviewing the established interfacing between the
applicant and Westinghouse in areas such as transmittal of pressurizer support
loads obtained by Westinghouse analysis and used by the applicant for design of
the support.
We did not find any deficiencies in the applicant's handling of interface matters.
One technical item came to our attention which had not been resolved and still
requires resolution. Due to the increased acceleration of the Hosgri response
spectra, the nozzle loadings on the steam driven auxiliary feedwater pump turbine
increased beyond the turbine manufacturer's rated allowable nozzle loadings. The
applicant will make the necessary modifications to reduce the nozzle loadings. We
will review the modification and provide our evaluation in a future supplement to
the Safety Evaluation Report.
3-68
3.9.3.9 Summary of Outstanding Items
As described in Sections 3.9.3.2 through 3.9.3.8 above we have concluded that,
subject to satisfactory resolution of a number of outstanding items, the applicant's
seismic reevaluation of the mechanical systems and components are acceptable. The
outstanding items are described in the individual sections above and are summarized
below. We will provide our evaluation of these outstanding items in a future
supplement to the Safety Evaluation Report.
(1) Submittal of a demonstration of the similarity between the Diablo Canyon
reactor coolant system and the reactor coolant system that was tested to
justify 4 percent dumping (Section 3.9.3.2).
(2) Submittal of additional information about the sensitivity of non-linear
systems in the reactor coolant system (parts of the reactor internals and
control rod drive mechanisms) to the synthesized time history motions used
for analysis and the significance of the time history selected
(Section 3.9.3.4.2).
(3) Submittal of a study of the effects on the reactor coolant system main loops
of using the Regulatory Guide 1.92 method of combining responses (Section
3.9.3.4.2).
(4) Submittal of an assessment of the differences, if any, in the reactor coolant
system main loop analysis for Unit 2 as opposed to the Unit I analysis that
was submitted for our review (Section 3.9.3.4.2).
(5) Submittal of additional information about support capacities for reactor
coolant system branch piping in order to assess the significance to those
supports of using the Regulatory Guide 1.92 method of combining responses.
(Section 3.9.3.4.3).
(6) Submittal of a study to assess the effects on other piping of using the
Regulatory Guide 1.92 method of combining responses, including consideration
of closely spaced modes (Section 3.9.3.4.4).
(7) Submittal of a study to assess the combined effects on other piping of actual
support stiffnesses, seismic anchor movements and response combinations
(Section 3.9.3.4.4).
(8) Submittal of information about the upgrading of supporting for Design Class 2.piping as necessary to ensure that Design Class 1 piping will perform its
intended safety function and to ensure the systems relied upon for cold
shutdown will perform their functions (Section 3.9.3.5).
3-69
(9) Completion of our evaluation of the applicant's piping snubber study (Section
3.9.3.6).
(10) Submittal of information concerning the results of requalification by testing
(Section 3.9.3.7).
(11) Submittal of additional information regarding the in-situ testing program
(Section 3.9.3.7).
(12) Submittal of additional justification for the test inputs to be used in
testing a 14 inch motor operated gate valve (Section 3.9.3.7).
(13) Completion of our review of the applicant's reports concerning qualification
of Limitorque valve actuators and their applicability to Diablo Canyon
(Section 3.9.3.7).
(14) Submittal of information concerning the natural frequency of one valve and
concerning the qualification of several other valves (Section 3.9.3.7).
(15) Submittal of information concerning the ability of active valves to operate
during a seismic event as well as afterwards (Section 3.9.3.7).
(16) Submittal of updating amendments for Tables 7-5 through 7-8 of Amendment 50
to the operating license application (Section 3.9.3.7).
(17> Submittal of information concerning modifications to reduce nozzle loadings
on the steam driven auxiliary feedwater pump (Section 3.9.3.8).
3-70
3.10 Seismic Qualification of Electrical Equipment
3.10.1 Introduction
In Sections 3.10 and 7.8 of the Safety Evaluation Report we indicated that we had
not completed our review of the qualification of safety-related electrical equipment.
Environmental qualification of electrical equipment is discussed in Section 7.8 of
this supplement.
Our evaluation of seismic qualification of electrical equipment is presented below.
A combination of previous qualification and requalification methodology is involved.
Some equipment is being requalified because (1) its previous qualification inputwas not adequate to envelope the current Hosgri event input, or (2) in our review
concerns were raised about the adequacy of the justification for the previous
qualification methods.
Some equipment does not need to be requalified because the previous qualification
basis was adequately severe to envelope the Hosgri event inputs and no concerns
were raised in our review about the previous qualification. This is not an unusual
result. Equipment is often qualified for more severe conditions than are required
in a particular application, especially when the equipment was qualified on a
generic basis by the manufacturer.
3.10.2 Criteria
The majority of the safety-related electrical instrumentation and control equipment
was qualified by testing. The balance was qualified by analysis, or a combination
of test and analysis. This equipment was previously qualified in accordance with
IEEE Standard 344-1971, "IEEE Guide for Seismic Qualification of Class I Electrical
Equipment for Nuclear Power Generating Stations," to the level of the double design
earthquake or higher. Where the original qualification level does not envelope the
required seismic inputs to equipment for the Hosgri event, the applicant has com-
mitted to requalify the equipment for the Hosgri required response spectra.
In the requalification process the applicant has, at our request, committed to
employ seismic qualification methods that conform to our current criteria
(Regulatory Guide 1.100, Revision 1, "Seismic Qualification of Electrical Equipment
for Nuclear Power Plants," August 1977, and IEEE Standard 344-1975, "IEEE
Recommended Practice for Seismic Qualification of Class 1E Equipment for Nuclear
Power Generating Stations").
3-71
This updating to current criteria applies to the seismic qualification methods
including shake testing methods and the type and severity of shaking employed. It
does not, however, include the aging requirements and other general environmental
qualification recommendations that are reflected in our current positi-ons for new
plants and are referenced in Regulatory Guide 1.100. Our current criteria for
environmental qualification for new plants are described in Regulatory Guide 1.89,
"Qualification of Class IE Equipment for Nuclear Power Plants," November 1974, and
IEEE Standard 323-1974, "IEEE Standard for Qualifying. Class 1E Equipment for Nuclear
Power Generating Stations," February 1974.
We requested the updating to current seismic qualification criteria to eliminate
the concerns discussed in the following paragraphs. We do not have similar require-
ments with respect to environmental qualification.
Earlier seismic qualification programs generally used single frequency, single axis
testing. As used here, the term single frequency means testing at a number of
different frequencies, one frequency at a time. Similarly, single axis testing
means excitation in one direction at a time. The current staff position is that
multi-frequency, multi-axis testing should generally be performed except in cases
where the characteristics of the required input motion indicate that the motion is
dominated by one frequency and the anticipated response of the equipment is ade-
quately represented by one mode, or that the single frequency input has sufficient
intensity and duration to excite all modes to the required amplitudes such that the
test response spectra envelopes the corresponding required response spectra of all
the modes.
Since the issuance of the newer standard, we have had one significant concern
regarding equipment qualified under the earlier standard: whether or not the
original testing or analysis can be justified in light of our current position
described above. To address this concern we have established a seismic qualifica-
tion review team. The team has been auditing qualification programs for operating
license applications since 1975 in order to assess the adequacy of seismic qualifi-
cation testing in light of current standards. Where there has been doubt that the
original qualification is justified, retesting or further justification has been
required.
The team visited the Diablo Canyon plant in 1977. The team inspected selected
vital mechanical and electrical equipment as installed and identified concerns
about the adequacy of original seismic qualification methods for some of the items
inspected. For those items where the team expressed concern, the applicant has
included the appropriate equipment among the items to be requalified by testing in
accordance with IEEE Standard 344-1975. This eliminated the team's concern. Our
evaluation of this equipment is discussed further in a section below entitled
"Balance-of-Plant Equipment."
3-72
The seismic qualification review team also visited Westinghouse Electric Corporation
in 1976 to audit qualification methods for equipment supplied as part of the nuclear
steam supply system at Diablo Canyon and other plants. Although no final evaluation
has yet been issued, all the equipment supplied as part of the nuclear steam supply
system at Diablo Canyon is being reviewed. Our evaluation is discussed further in
Section 3.10.4 below.
The origirral seismic qualification was performed in accordance with standards that
apply to a plant of this vintage. This original qualification has been reviewed to
ensure that the original methods are adequately justified in light of current
standards. Requalification according to the current standards is being performed
either where necessitated by changes in seismic inputs or where our review revealed
concerns about the justification for the original qualification. We have found in
our review of this plant, as we have in reviewing other operating license applica-
tions, that these criteria provide reasonable assurance that safety-related electri-
cal equipment will function as intended before, during and after a safe shutdown
earthquake (Hosgri event for this plant). For these reasons, we have concluded
that the criteria used in the seismic qualification of safety-related electrical
equipment are acceptable.
Our evaluation of the seismic qualification of the equipment is provided in the
following sections of this supplement.
3.10.3 Balance-of-Plant Equipment
Equipment that is outside the scope of the nuclear steam supply system (balance-of-
plant equipment) was originally qualified in accordance with IEEE Standard 344-1971.
The qualification of this equipment is described in the Final Safety Analysis
Report. We have reviewed that material.
Equipment to be Retested
Some balance-of-plant equipment is to be requalified by retesting, either because
the seismic input has increased beyond the original qualification level or because
of concerns we raised about the justification for the original qualification methods
in light of current standards. As described in Section 3.10.2 above, the applicant
has committed to perform this retesting in accordance with IEEE Standard 344-1975
and Regulatory Guide 1.100, and these criteria are acceptable.
For equipment that will be retested, we will review the results of the retesting
when they are available and provide our evaluation in a future supplement to the
Safety Evaluation Report.
3-73
EauiDment Not to be Retested
For equipment that will not be retested, we reviewed the qualification records at
the meetings during the week of January 23, 1978. The questions resulting from
that audit were documented in our summary of the meeting. The applicant has re-
sponded to a number of those questions informally. The informal responses indicated
that some sections of the Final Safety Analysis Report would be revised. After
reviewing these responses, the following areas remain outstanding in our review of
this equipment:
(1) Documentation in an amendment to the Final Safety Analysis Report of the
informal responses that have already been reviewed.
1
(2) At the meetings during the week of January 23, 1978, detailed information
regarding the qualification of devices (indicators and controllers) located on
various instrument panels was not available. This information has not yet
been provided. When it is submitted we will review it and provide our evalua-
tion in a future supplement to the Safety Evaluation Report.
For balance-of-plant equipment that will not be retested, we have found in our
review that, subject to satisfactory resolution of the open items described above,
the original seismic qualification conforms to IEEE Standard 344-1971 with adequate
justification for the qualification methods and is, therefore, acceptable. We will
provide our evaluation of the outstanding items described above in a future supple-
ment to the Safety Evaluation Report.
3.10.4 Nuclear Steam Supply System Equipment
Mechanical Aspects
With regard to qualification methods, including test procedures and the types of
seismic excitation, we have reviewed the seismic qualification of equipment supplied
as part of the nuclear steam supply system. Qualification of much of this equipment
is documented in the following Westinghouse Topical Reports which apply specifically
to Diablo Canyon: WCAP-8941, "Seismic Qualification of the Rotary Relay for use in
the Trojan and Diablo Auxiliary Safeguards Cabinets," October 1977, WCAP-8021,
"Seismic Testing of Electrical and Control Equipment (PG&E Plants)," May 1973 and
WCAP-8021 Supplement 1, "Seismic Testing of Electrical and Control Equipment (Engi-
neering Safeguards Test Cabinet for PG&E Plants)," May 1977.
Qualification of other nuclear steam supply system equipment for Diablo Canyon is
documented in several other Westinghouse topical reports that are not specific to
Diablo Canyon as described in Chapter 10 of Amendment 50 to the operating license
application.
As mentioned in Section 3.10.2 above, the seismic qualification review team has
visited Westinghouse to review the justification for the original tests in light of
3-74
current standards (Regulatory Guide 1.100 and IEEE 344-1975). The concerns identi-
fied have been resolved by retesting or by further justification. With the possible
exception of the solid state protection system cabinets mentioned below, none of
this equipment needed retesting on account of the Hosgri event because the previous
qualification inputs enveloped the Hosgri event inputs. We have found in our
review that the general methods, including the seismic test procedures and the type
of test inputs used, conform to the criteria discussed in Section 3.10.2 above with
adequate justification except for the qualification of the solid state protection
system cabinets for the Hosgri event which will require further justification. We
will provide our evaluation of this item in a future supplement to the Safety
Evaluation Report. Subject to satisfactory resolution of this matter the general
methods for seismic qualification of nuclear steam supply system equipment, including
the seismic test procedures and the type of test inputs employed are, therefore,
acceptable.
Electrical Aspects
With regard to the manner in which the nuclear steam supply system equipment under
test was operated during testing and the manner in which the equipment's performance
was monitored, we have not completed our evaluation. These aspects are important
in establishing the equipment's capability to operate as designed-- before, during
and after a seismic event. We will provide our evaluation of this matter in a
future supplement to the Safety Evaluation Report.
3.10.5 Documentation
At the meetings during the weeks of January 23, 1978 and January 30, 1978 and in
subsequent informal meetings we found the information in Table 10-1 of Amendment 50
to the operating license application was incomplete or inconsistent with the infor-
mation we have informally received. We will require that the applicant update this
information in an Amendment to the operating license application and will provide
our evaluation in a future supplement to the Safety Evaluation Report.
3.10.6 Summary of Outstanding Items
As described in Sections 3.10.2 through 3.10.5 above, we have found the qualifica-
tion of safety-related equipment acceptable subject to satisfactory resolution of
several outstanding items. The outstanding items are summarized below. We will
provide our evaluation of these matters in a future supplement to the Safety Evalua-
tion Report.
(1) Submittal of results of retesting for balance-of-plant equipment that is being
retested (Section 3.10.3).
3-75
(2) Documentation of informal responses that have been reviewed for
balance-of-plant equipment that is not being retested (Section 3.10.3).
(3) Submittal of detailed information regarding the qualification of
balance-of-plant devices located on various instrument panels that are not
being retested (Section 3.10.3).
(4) Submittal of further justification for the qualification of the solid state
protection system in the nuclear steam supply system scope (Section 3.10.4).
(5) Completion of our evaluation of the manner in which nuclear steam supply
system equipment was operated and monitored during testing (Section 3.10.4).
(6) Submittal of updating information for Table 10-1 of Amendment 50 to the
operating license application (Section 3.10.5).
3-76
Figure 3-1. Schematic Layout of Diesel Generator Cable Spreading Rooms andSwitchgear Rooms in the Turbine Building
/ ,T SHADOWING BY CONTAINMENT
AD AUXILIARY BUILDING
r-- ROOM ASSOCIATED WITH SWING DIESEL
STEEL SIDINGDESIGNED FOR200 MPH TORNADOWITHOUT MISSILES
12"BLC
.) )
REINFORCED CONCRETEOCK
TURBINE BUILDING
24" REINFORCED CONCRETE
UKwJ
8" REINFORCEDCONCRETEBLOCK
-
ADDITIONAL CONCRETE BLOCKWALLS- UNIT 1 SIDE ONLY
.)
UNIT 1 SIDE UNIT 2 SIDE
NOTES: 1. CABLE SPREADING ROOMS ARE AT EL. 104', 19 FEET ABOVE GRADE,WITH 10" REINFORCED CONCRETE CEILINGS
2. SWITCHGEAR ROOMS ARE DIRECTLY ABOVE, IN SIMILAR LAYOUT,AT ELEVATION 119', 34 FEET ABOVE GRADE, WITH 12" REINFORCEDCONCRETE CEILINGS
Figure 3-2. Layout of Vulnerable Main Steam Relief Valves andCable Trays Outside of Plant
AUXILIARY BUILDINGIIII
RELIEF VALVES(GENERATORS
I 3AND4
UNIT IUNIT 2CONTANMENTSIMI LAR
D
• t 9
FIGURE 3-3DIABLO CANYON SEISMIC REEVALUATIONCOMPARISION OF HOSGRI EVENT SPECTRA
2.0- T = 0.0 FOR SMALL STRUCTURES, 7% DAM
- HOSGRI 7.5M/NEWMARK
"vi '---- HOSGRI 7.5M/BLUME
HOSGRI 7.5M/BLUME REDUCI
1.6-
"-
0.8
-J0
w
IPING
ED FOR DUCTILITY WITH /u=i.3
FREQUENCY, HERTZ
FIGURE 3-4DIABLO CANYON SEISMIC REEVALUATIONCOMPARISON OF HOSGRI EVENT SPECTRA
Yu~rI r= 0.04 FOR CONTAINMENT STRUCTURE AND INTAKE STRUCTURE
S- -HOSGRI 7.5M/NEWMARK
- --- HOSGRI 7.5M/BLUME
HOSGRI 7.5M/BLUME REDUCED FOR DUCTILITY WITH A=1.3
z
0
I-
Lu
Lu
0.U4
10.6-
f \%
1.2.
0.8
0.67g
0.4
0
0.00 4 12 16 20 24 28 32 36 40
FREQUENCY, HERTZ
FIGURE 3-5DIABLO CANYON SEISMIC REEVALUATIONCOMPARISON OF HOSGRI EVENT SPECTRA
2.0 T= 0.052 FOR AUXILIARY BUILDING 7
--.- HOSGRI 7.5M/NEWMARK
------ HOSGRI 7.5M/BLUME
HOSGRI 7.5M/BLUME RE[
_- 1.6 I Iz AUXILIARY BUILDING
ii1.2
Sw
- 0.8
0w
'% DAMPING
)UCED FOR DUCTILITY WITH A=1.3
-I IT
40
FREQUENCY, HERTZ
FIGURE 3-6DIABLO CANYON SEISMIC REEVALUATIONCOMPARISON OF HOSGRI EVENT SPECTRA
2.0- 2" =0.08 FOR TURBINE BUILDING 7% D
HOSGRI 7.5M/NEWMARK
HOSGRI 7.5M/BLUME
HOSGRI 7.5M/BLUME RE[1.6
z- /\
; 1.22
Lu-jLu
' 0.8-LLA
I-
0cl)
AMPING
)UCED FOR DUCTILITY with IA=1.3
FREQUENCY, HERTZ
, I I I
5.0 REACTOR COOLANT SYSTEM
5.2 Integrity of Reactor Coolant Pressure Boundary
5.2.4 Fracture Toughness
In Section 5.2.4 of the Safety Evaluation Report, we found the reactor coolant
system fracture toughness provisions acceptable based upon our review of the
materials selection, toughness requirements and the extent of materials testing
proposed by the applicant.
In addition, although not specifically mentioned in the Safety Evaluation Report,
some results from fracture toughness testing of the Unit I reactor vessel materials
were available and we had reviewed them. Subsequently, in Amendment 43, similar
results from fracture toughness testing of the Unit 2 reactor vessel were provided
and we reviewed them. These data indicated that the reactor vessel complied withthe requirements of the ASME Boiler and Pressure Vessel Code and were, therefore,
considered acceptable.
Our review of information received from reactor vessel surveillance programs has
indicated that materials in older vessels may have a wider variation in sensitivity
to radiation damage than was initially anticipated. In addition, it has been
indicated that the reactor vessel surveillance program may not represent all of
the heats of material used in the reactor vessel beltline region. Although our
review of this information did not reveal a basis for concern about reactor vesselintegrity over the first several years of operation, it did indicate a need for
detailed review of the materials employed in reactor vessel construction and a
review of the specimens employed in the surveillance program to determine if thepresent specimens reasonably represent the limiting materials in the reactor
vessel beltline region.
We requested more detailed information on this subject in a letter to the applicant
dated November 23, 1977 so that we may evaluate the potential for developing
marginal fracture toughness properties after a period of years and assess the needfor augmented material surveillance. The applicant submitted this information in
Amendment 61 to the Final Safety Analysis Report. We have not completed our
review of this information. When we complete our review, we will provide our
evaluation in a future supplement to the Safety Evaluation Report.
5-1
6.0 ENGINEERED SAFETY FEATURES
6.2 Containment Systems
6.2.1 Containment Functional Design
Background
In Section 6.2.1 of the Safety Evaluation Report and Supplement Nos. 2 and 3 to
the Safety Evaluation Report, we presented our evaluation of the applicant's
subcompartment pressure calculations. We found these calculations acceptable.
In Section 6.2.1 of Supplement Nos. 3 and 4 to the Safety Evaluation Report, we
discussed a generic problem concerning the calculation of blowdown forces on the
reactor vessel that could result from a postulated loss-of-coolant accident at the
reactor vessel nozzle. We also discussed the consequences of this problem,
particularly for the reactor vessel supports. We concluded in Supplement No. 4
that continued licensing of plants for operation while our generic review was
still in progress would be acceptable.
Since then, we have decided that this matter must be acceptably resolved for this
plant prior to licensing. The applicant has determined the effects of reactor
coolant pipe breaks and steam and feedwater pipe breaks in the reactor vessel
cavity, the pressurizer subcompartment and the steam generator compartment. The
calculated loads due to these postulated pipe breaks have been combined with the
calculated seismic loads resulting from the Hosgri 7.5M event in order to judge
the adequacy of reactor coolant system supports and components. The applicant's
analyses were documented in letters from the applicant dated February 14, 1978 and
May 11, 1978 and in the Westinghouse Topical Reports WCAP-9241 (Proprietary) and
WCAP-9242 (Non-Proprietary), "Evaluation of the Reactor Coolant System for
Postulated Loss-of-Coolant Accident for the Diablo Canyon Nuclear Power Plant,"
submitted on January 20, 1978.
For the combined load conditions, our evaluation of the reactor coolant system is
provided in Section 3.9 of this supplement and our evaluation of the reactor fuel
is presented in Section 6.3.3 of this supplement. Our evaluation of the subcom-
partment pressure calculations that were used as part of this combined load deter-
mination is provided below.
Reactor Cavity - Reactor Coolant System Rupture
The-applicant used the Westinghouse Electric Corporation TMD code, with the compres-
sibility factor and without the augmented critical flow correlation, to analyze
the response of the reactor cavity to postulated ruptures of the reactor coolant
6-1
system hot and cold leg pipes. The maximum credible break size and locations were
identified by the applicant to be a 115-square inch cold leg break and a 76-square
inch hot leg break at the pipe-to-reactor vessel inlet and outlet nozzle welds,
respectively. Pipe displacement restraints have been provided to limit the break
sizes to those values. The reactor cavity was modeled using 60 nodes; 32 nodes
representing the free volume between the shield wall and the pressure vessel,
17 nodes representing compartments and passages within the shield wall and 11 nodes
external to the shield wall. The annulus between the reactor vessel and the
shield wall was divided into axial and circumferential nodes. The applicant also
presented the results of a nodalization sensitivity study which indicates that the
60 node model selected is adequate to determine the maximum asymmetric pressure
forces which may act upon the reactor vessel.
We have reviewed the applicant's input assumptions and parameters used in their
analysis of the reactor cavity transient response and the nodalization sensitivity
study. We have previously reviewed the computer code used by the applicant
(TMO code) as part of the NRC topical report evaluation program. The TMD code was
submitted for our review in the Westinghouse Topical Reports WCAP-8077 (Proprietary)
and WCAP-8078 (Non-proprietary), "Ice Condenser Containment Pressure Transient
Analysis Methods," March 1973. Our evaluation was presented in a letter dated
December 18, 1.973 to Westinghouse. We found that the methods described were
acceptable for containment pressure response calculations provided that
non-augmented critical flow relationships were used rather than augmented critical
flow relationships. The applicant has complied with this provision in performing
calculations for Diablo Canyon. We have performed confirmatory subcompartment
analyses for other plants analyzed with the TMD code and have found good agreement
between other applicants' results and our results. Based on our review, we have
concluded that the applicant's reactor cavity analysis is acceptable for the
design evaluation of the reactor vessel supports.
Pressurizer Enclosure - Reactor Coolant System Ruptures
The applicant modeled the pressurizer enclosure using three axial nodes. The TMD
code was used to calculate the pressurizer enclosure response for a postulated
double-ended rupture of the pressurizer spray line. The applicant has not further
subdivided the pressurizer enclosure free volume to determine the maximum differ-
ential pressures which could be experienced across the pressurizer vessel because
of asymmetry in the flow path around and past the vessel. Instead, the applicant
has conservatively assumed that the maximum calculated pressure (7.8 pounds per
square inch gauge) within the enclosure to act uniformly across the projected area
of the pressurizer vessel (including its insulation); this results in a
140,000-pound side load. The applicant has used this load in evaluating the
adequacy of the pressurizer supports. Based on the nature of the calculations, we
concur with the applicant's proposal that the assumed pressure load conservatively
bounds the maximum differential pressure loads which could result from the
6-2
asymmetry in the flow path around and past the pressurizer vessel. We therefore
have concluded that the applicant's assumed load is acceptable for the design
evaluation of the pressurizer supports.
Steam Generator Compartments - Secondary System Ruptures
The applicant has not performed independent subcompartment analyses to determine
the maximum asymmetric pressure loads which could act across the steam generators
in the unlikely event of a secondary steam system pipe rupture in the steam gener-
ator subcompartment. The applicant has instead stated that the peak asymmetric
pressure loads calculated to act on the steam generators in the event of a secondary
system pipe rupture for the D. C. Cook, Unit 2 plant (Docket No. 50-316) are more
severe than the peak asymmetric pressure loads possible for the Diablo Canyon
steam generators. The D. C. Cook, Unit 2 loads were then used to evaluate the
Diablo Canyon steam generator supports.
To justify this approach, the applicant has drawn comparisons between the steam
generator enclosures and steam line layouts at Diablo Canyon and D. C. Cook Unit 2.
In the D. C. Cook plant, the steam generator enclosure is a closed compartment
because of the design requirement to prevent steam bypassing the ice condenser.
As a result, the steam domes of the steam generators are fully enclosed. The
compartments only communicate with the relatively small containment lower (loop)
compartments. The main steam line exits the top of the steam generator, turns
1800 and runs downward between the steam generator vessel and the enclosure wall
before exiting into the reactor coolant system loop compartment on its way out of
the containment building. Due to the confining nature of the steam generator
enclosure and the asymmetry in the flow path around and past the steam generator
vessel, large asymmetric pressure forces are generated for assumed steam line
breaks within the enclosure.
In contrast, the steam generator compartments in the Diablo Canyon plant are not
closed at the top, but communicate directly with the main containment volume. The
main steam lines exit at the top of the steam generators turn 90 degrees and runhorizontally through the open main containment volume until they pass through the
crane wall and enter the steam tunnels. The steam tunnels are not in direct
communication with the steam generator compartments.
The applicant has used the loads calculated in the D. C. Cook Unit 2 steam generator
enclosure response analysis for two postulated steam line ruptures to evaluate the
adequacy of the Diablo Canyon steam generator supports. For a double-ended rupture
of the steam line at the top of the steam generator vessel (exit nozzle-to-pipeweld) the D. C. Cook steam generators are subjected to 800,000-pound downward
loads and 100,000-pound side loads. For a double-ended rupture of the steam line
in the vertical run between the steam generator and the enclosure wall, the
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D. C. Cook steam generators are subjected to one million-pound side loads and
200,000 pound upward loads. These loads were considered by the applicant in the
evaluation of the steam generator supports for the Diablo Canyon plant.
Based on our review of the D. C. Cook Unit 2 steam generator subcompartment analyses
and the comparison of the D. C. Cook and Diablo Canyon steam generator enclosure
designs, we concur with the applicant's statement that the steam generator loads
calculated for the postulated steam line ruptures in the D. C. Cook Unit 2 plant
are more severe than the loads which could result from secondary system pipe
ruptures at the Diablo Canyon plant. Since, in evaluating the Diablo Canyon steam
generator supports for secondary system pipe breaks, the applicant has used greater
loads than are possible at Diablo Canyon from this type of rupture, we have concluded
that the applicant's design approach for the Diablo Canyon steam generator supports
is acceptable when considering secondary system piping ruptures.
Loop Compartments - Reactor Coolant System Ruptures
The applicant has also reanalyzed the containment loop compartments for assumed
double-ended reactor coolant system cold and hot leg pipe breaks within the loop
compartments. For this analysis, the applicant used the Westinghouse Electric
Corporation TMD code, with the compressibility factor and without the augmented
critical flow correlation, to analyze the response of the subcompartments. The
loop compartments were modeled using six control volumes. The compartments outside
the crane wall were modeled as eleven additional subcompartments and one additional
node was utilized to model the main containment volume above the 140-foot level
deck. The maximum calculated differential pressure across the lower portion of
the steam generators, which are in the loop compartments, is 6.04 pounds per
square inch for the postulated hot leg break, and 4.48 pounds per square inch for
the postulated cold leg break. In contrast, the applicant has assumed a differen-
tial pressure of 20 pounds per square inch across the portion of the steam gener-
ators within the loop compartments in evaluating the steam generator supports. We
have reviewed the applicant's subcompartment nodalization and input parameters and
conclude that the analyses performed are acceptable for the purpose of evaluating
the adequacy of the steam generator supports for postulated reactor coolant system
pipe ruptures within the loop compartments.
Conclusions
As discussed above we have concluded that the applicant's analyses of asymmetric
pressure loads are acceptable.
We consider these matters resolved.
6-4
6.2.3 Containment Air Purification and Cleanup Systems
In Section 6.2.3 of the Safety Evaluation Report, we discussed the normal contain-
ment purge system. We noted that it was designed for use during normal plant
operation and served no post-accident function. We found it acceptable.
Our Branch Technical Position CSB 6-4, "Containment Purging During Normal Plant
Operations," November 1975, describes design provisions and analytical methods
that are acceptable for providing assurance that this system will not signifi-
cantly increase the calculated doses due to an accident if the system is in use
when an accident occurs. Since we are currently using this position to evaluate
applications, we have requested that the applicant address this position. We will
review this information when it is submitted and will report the results of our
evalution in a future supplement to the Safety Evaluation Report.
6.3 Emergency Core Cooling System (ECCS)
Metal Water Reaction Heat Rates
In Section 6.3 of Supplement No. 6 to the Safety Evaluation Report, we found the
emergency core cooling system acceptable.
On March 23, 1978, Westinghouse informed us that they had discovered an error in
the LOCTA program used to calculate peak cladding temperatures in their emergency
core cooling system evaluation model. On March 29, 1978 Westinghouse made a
detailed presentation to the staff on the subject. The error, which also existed
in the SATAN code, had the effect of causing the metal-water reactor heat release
tb be one-half of what it should be. The error and its confirmation were explained.
Westinghouse had performed preliminary calculations with the error corrected which
showed that some plants would not meet the 2200 degrees Fahrenheit limit of
Section 50.46 of 10 CFR Part 50. Therefore, in order to avoid reductions in
overall peaking factor, other compensating changes were recommended in their
evaluation model.
It has been possible to provide suitable adjustments to the allowable total peaking
factor on other plants, such as D. C. Cook, Unit 2 (Docket No. 50-316), in order
to ensure that plant operation is in compliance with the Commission's emergency
core cooling system requirements pending our evaluation of the compensating factors
proposed by Westinghouse. Should it become necessary, this can be done for Diablo
Canyon as well. In addition, we expect that within a few months the proposed
compensating factors will be reviewed and their suitability determined. We will
report the results of our evaluation of this matter for Diablo Canyon in a future
supplement to the Safety Evaluation Report.
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Seismic Reevaluation
As part of the seismic reevaluation the applicant has evaluated the response of
the reactor coolant system to calculated earthquake loads combined with calculated
loads from a postulated simultaneous loss-of-coolant accident. Section 3.9 of
this supplement discusses the effect of these combined loads on the reactor coolant
system, except for the reactor fuel.
The limiting case with regard to fuel design results from combining earthquake
loads for a Hosgri event with loss-of-coolant accident loads for a pipe break at
the reactor vessel nozzle. Due to the nature of the intertia forces involved, the
calculated loads on the outer fuel assemblies are greater than those on the inner
assemblies. For the outer fuel assemblies the combined calculated loads exceed
our acceptance criteria for the spacer grids between the individual fuel rods.
Thus, we consider that some deformation of the spacer grids in these fuel assemblies
would occur for this combination of loads.
The requirement for this combination of loads is to demonstrate that the reactor
core maintains a coolable geometry in accordance with 10 CFR Part 50.46, "Acceptance
Criteria for Emergency Core Cooling Systems for Light Water Cooled Nuclear Power
Reactors." The applicant has proposed to demonstrate this by (1) assuming an
amount .of deformation in the outer assemblies that is conservative with respect to
the calculated loads and (2) emergency core cooling calculational models to deter-
mine peak cladding temperatures with the assumed geometry.
The applicant's proposal was documented in a letter dated February 21, 1978
enclosing a report on the calculations performed by Westinghouse. At a meeting
with the applicant on April 11, 1978 we discussed the calculations and informed
the applicant that additional information would be required. We are still
discussing these criteria and the nature of the calculations with the applicant.
We will review this information when it is available and provide our evaluation in
a future supplement to the Safety Evaluation Report.
6-6
7.0 INSTRUMENTATION AND CONTROL
7.2 Reactor Trip System
In Section 7.2.2.4 of Supplement No. 3 to the Safety Evaluation Report, we found
the reactor trip system acceptable subject to satisfactory seismic qualification.
Seismic qualification is discussed in Section 3.10 of this supplement.
In a letter dated February 21, 1978 the applicant stated that a seismic scram
system would be installed. The system described by the applicant in the letter
will be qualified for seismic conditions. The sensors are three accelerometers
spaced around the containment base slab. Each one will sense accelerations in
three mutually orthogonal directions. A reactor trip signal would be generated
upon sensing O.4g or greater acceleration in any one direction at two of the three
sensors.
Our generic studies of this subject, which are continuing, have to date indicated
neither a substantial safety advantage nor a substantial disadvantage from incorpora-
tion of a seismic scram. Therefore, we do not currently require a seismic scram
device although we have no objection to it. This subject has been discussed with
the Advisory Committee on Reactor Safeguards, as mentioned in Appendix B to this
supplement and Appendix B to Supplement No. 6 to the Safety Evaluation Report.
Since the applicant is proposing to install a seismic scram and since the additional
scram circuit could affect other protection system circuitry, we must review and
evaluate it. We consider the basic system proposed by the applicant to be
acceptable. It has a high setpoint which will initiate a scram for a severe
earthquake but not for a mild one. The high setpoint combined with the two-out-of-
three logic and the location of the sensors will tend to prevent scrams due to
spurious events that are not real earthquakes. On the other hand, the failure of
a single sensor to develop a trip signal would not prevent a scram.
We will require further information from the applicant regarding how the system
will satisfy our requirements for our separation, isolation quality, testability
and qualification for Class IE circuits.
We will review this information when it is received and provide our evaluation in
a future supplement to the Safety Evaluation Report.
7.4 Systems Required for Safe Shutdown
In Section 7.4 of the Safety Evaluation Report we discussed the instrumentation
and control systems reo'.ired for safe shutdown. We found the systems acceptable.
7-1
As discussed in Section 3.2.1 of this supplement, we have recently reviewed the
systems necessary to achieve cold shutdown following the Hosgri event. As part of
our review we will require further information about the system function indication
available to the operator in the control room in connection with performing the
shutdown. We will provide our evaluation of this matter in a future supplement to
the Safety Evaluation Report.
7.8 Environmental and Seismic Qualification
In Sections 3.10 and 7.8 of the Safety Evaluation Report, we stated that our
review of the environmental and seismic qualification of safety-related electrical
equipment had not been completed. This is still the case.
The current status of our review of the seismic qualification of this equipment is
provided in Section 3.10 of this supplement. The status of our review of environ-
mental qualification is provided below.
Environmental Qualification - Submerged Electrical Equipment
We requested that the applicant identify all of the electrical equipment and
components required for safety that may be submerged as the consequence of a
loss-of-coolant accident and address the resultant effects on plant safety. The
applicant provided a report on this subject in Amendment 47 to the Final Safety
Analysis Report and supplemented this material with letters dated October 3, 1977
and February 15, 1978. The applicant has identified various instruments, annunci-
ators and valves as being vulnerable to malfunction due to submergence.
Instruments identified include reactor coolant system pressure, pressurizer level,
and steam generator narrow range level. The applicant has indicated that these
instruments will be replaced with components that can be qualified for submerged
service by testing. For the remaining items that were identified as being
vulnerable, we have reviewed the applicant's justification and concur with the
applicant's conclusion that submergence has no impact, direct or indirect, on any
safety function.
Since the applicant will qualify the instruments discussed above for submerged
conditions and has demonstrated that the possible malfunction of other equipment
due to submergence will have no impact on plant safety, we have concluded that
these provisions are acceptable.
We will review the results of the qualification testing for the instruments discussed
above and provide our evaluation in a future supplement to the Safety Evaluation
Report.
7-2
Environmental Qualification - Containment Fan Cooler Motors
These motors have been supplied as part of the nuclear steam supply system for
Diablo Canyon. As indicated in the Final Safety Analysis Report, type tests have
been performed to demonstrate environmental qualification of the fan cooler motor
units for operation in the post-accident environment. These type tests were
undertaken by the applicant to meet the requirements of IEEE 334-1971, "Guide for
Type Tests of Class 1 Motors Inside the Containment of Nuclear Power Generating
Stations." The type test, procedures and data are documented in the Final Safety
Analysis Report by reference to the Westinghouse Topical Report, WCAP-7829, "Fan
Cooler Motor Unit Tests."
The type test, described in the topical report, includes component tests and a
test of a 20 horsepower sample motor. We have reviewed these tests and have
concluded (1) that the tests performed are in compliance with the provisions of
IEEE 334-1971 and are, therefore, acceptable, and (2) that the 20 horsepower
sample motor's insulation system was shown to perform satisfactorily with winding
hot spot temperatures reaching 122 degrees Centigrade.
The winding hot spot temperature was achieved by applying a hotter than normal
external heat environment. However, it is primarily internal heat associated with
full-load current that produces winding hot spot temperatures in a full size
motor. We concluded that the method used to qualify, using an external instead of
internal heat source, would not significantly affect the full-size motor's
qualification provided the full size motor's hot spot temperature could be maintained
below qualified levels.
In response to our request, the applicant provided additional information in
letters dated October 3, 1977, January 19, 1978 and February 10, 1978. This
included results of motor rise calculations that are based on engineering tests of
typical motors. These calculations demonstrated that the total temperature of the
motor (cooling air inlet plus winding rise temperature) will not exceed qualified
levels for the winding hot spot temperature. In addition, the information included
the results of a heat transfer analysis that demonstrates the capability of the
motor's heat exchanger to provide cooling air inlet to the motor's windings given
the worst case steam line break accident environment (which results in the highest
calculated containment temperatures).
Based on these calculations and the results of the heat tansfer analysis, we have
concluded that reasonable assurance exists that the motor will function properly
when required and the environmental qualification of this motor is, therefore,
acceptable.
7-3
Environmental Qualification - Balance of Plant Class IE Equipment Exposed to
Normal Environments
This discussion concerns balance-of-plant equipment that is exposed to normal
environments, i.e., not in containment and not exposed to a postulated steam line
break environment outside containment.
With regard to the environmental qualification of balance-of-plant equipment
(equipment not supplied as part of the nuclear steam supply system), we requested
that the applicant provide the test program, test data, and test results for
representative safety-related electrical equipment in each of the following
categories: switchgear, motor control centers, valve operators, motors, logic
equipment, cable, and diesel generator control equipment. The applicant supplied
qualification information based on current industry standards for these specific
types of electrical equipment in Amendment 47 to the Final Safety Analysis Report
and in letters dated October 3, 1977 and December 5, 1977.
The industry standards are based on operating experience and consider the effects
of environment on electrical equipment. These standards allow tests based on
temperature rise limitations to be performed at the environment existing at the
test facility location rather than requiring testing at the extreme ends of the
specified temperature range. For example, properly testing a motor at an ambient
temperature of 30 degrees Centigrade in accordance with the industry standard and
meeting appropriate temperature rise limitations will qualify the motor for service
in ambient temperatures from 10 degrees Centigrade to 40 degrees Centigrade.
Equipment tested in accordance with the industry standard temperature rise limita-
tions have demonstrated, through operating experience, their satisfactory operation
over a normal range of environments. It is thus our conclusion that equipment
tested to industry standards and operated within the normal range of environments
specified in the standards will function properly when required.
We were concerned, however, that testing balance-of-plant equipment in conformance
with the industry standards might not be sufficient to encompass all areas of the
plant where such electrical equipment is located. The forced ventilation systems
may not have the capacity to maintain specified normal temperatures during extreme
outside climatic conditions or may not be available at all times during the life-
time of the plant. As a result, electrical equipment may be exposed to a more
severe environment than the normal range of environments specified in the industry
standards.
We requested that the applicant review all balance-of-plant safety-related elec-
trical equipment outside the containment to determine that each item of equipment
is qualified to the full range of environments to which it may be exposed and in
which it may be essential that the equipment operate. As a result, the applicant
identified areas where allowable temperatures may be exceeded during extreme
7-4
outside climatic conditions. The temperature excesses were expected to be small
and to occur infrequently, if at all. For these areas, the applicant has committed
to providing a temperature monitoring system to alert the operator when the speci-
fied temperature limits are exceeded. The monitoring system will include instru-
ments which are of a high qualify, are testable, and are powered from a reliable
power source.
We have reviewed the proposed environmental temperature monitoring system for the
areas where balance-of-plant equipment is located and conclude that it provides
the necessary information to the operator with regard to excess temperature environ-
ment conditions, if and when they occur. If the qualification temperature for any
of this equipment is exceeded during the plant life, the applicant has committed
to maintain a record of such occurrence, report the occurrence, and provide analyses
to demonstrate the continued acceptability of the equipment. We will include
appropriate requirements to this effect in the Technical Specifications. Since if
any temperature excesses occur they are expected to be small and infrequent, the
expected effect would be a gradual shortening of the equipment's service life
rather than sudden failure. This would allow time to evaluate the equipment and,
if necessary, to take corrective action. The temperature monitoring system provides
the information necessary to follow such an approach.
We have concluded that this is acceptable for the qualification of balance-of-plant
electrical equipment exposed to normal environments outside the containment for
Diablo Canyon Units I and 2, since the equipment has been qualified for a range of
normal environments in accordance with industry standards and since, if temperatures
outside the range of qualified temperatures occur, there will be ample time to
evaluate the equipment's remaining service life and take corrective action if
necessary.
Environmental Qualification - Nuclear Steam Supply System Equipment
Exposed to Normal Environments
Some equipment exposed to normal environments outside containment was supplied as
part of the nuclear steam supply system (rather than being within the balance-of-
plant scope). We did not request that the applicant describe the qualification of
nuclear steam supply system equipment for normal environments in the same manner
as we did for balance-of-plant equipment.
As indicated in the discussion above for balance-of-plant equipment, this concern
involves the possibility of occasionally exceeding the qualified temperature range
by a small amount. The expected effect is a gradual shortening of the equipment's
service life rather than sudden failure. In light of the nature of this concern,
its expected consequences and our experience in reviewing balance-of-plant equipment
we do not consider it necessary that we review the qualification of nuclear steam
supply system equipment for normal environments in the same detail as we reviewed
balance-of-plant equipment.
7-5
Instead, we will require that the applicant establish the qualified temperature
range for the equipment and provide an appropriate ambient temperature monitoring
program as was done for the balance-of-plant equipment. We conclude that such a
program will be an acceptable means for ensuring the qualification of nuclear
steam supply system electrical equipment exposed to normal environments outside
the containment for Diablo Canyon Units 1 and 2, since, if temperatures outside
the range of qualified temperatures occur, there will be ample time to evaluate
the equipment's remaining service life and take corrective action if necessary.
After the applicant documents such a proposed program we will report the final
resolution of this matter in a future supplement to the Safety Evaluation Report.
Environmental Qualification - Class 1E Equipment Exposed to Severe Environments
We have requested that the applicant provide a list of all equipment that may be
required to function in a severe environment. This list will include both equip-
ment in the balance-of-plant scope and in the nuclear steam supply scope. The
list will include mostly equipment located inside containment that is required to
operate under steam-line break conditions or loss-of-coolant accident conditions.
It will also include some equipment located outside containment that is required
to operate after exposure to the severe environment resulting from a postulated
pipe break. The list will be more specific than the information we have now,
including the manufacturer's name, the model number, the location and a specific
reference to the qualification report for each piece of equipment. In order to
complete our review of this subject, we will audit certain items from the list and
review the detailed qualification records for those items.
We will report the results of this review in a future supplement to the Safety
Evaluation Report.
Environmental Qualification - Open Items
The items that remain open in our review of the environmental qualification of
Class IE equipment for Diablo Canyon, as discussed above and elsewhere, are sum-
marized below.
(1) A review of the qualification test results for submerged equipment when
available (discussed above).
(2) Documentation from the applicant of a program for monitoring the ambient
temperature of equipment supplied within the scope of the nuclear steam
supply system and exposed to normal environments outside the containment
(discussed above).
7-6
(3) A review and audit of the detailed qualification records for equipment exposed
to severe environments inside and outside containment, balance-of-plant scope
and nuclear steam supply system scope (discussed above).
(4) Our review of the calculated temperature inside containment for a steam line
break accident has not been completed. When this matter is resolved, if the
temperature exceeds the qualified capabilities of any equipment, further
evaluation will be required. (Discussed in Section 6.2.1 of Supplement No. 6
to the Safety Evaluation Report)
(5) In addition, as a result of problems that have arisen recently with the
qualification of several types of equipment in other reviews, we have requested
from the applicant detailed information to justify the qualification of
Diablo *Canyon equipment in the specific area listed below. (To be discussed
in a future supplement to the Safety Evaluation Report)
(a) Connections (splices, connectors or terminal blocks subject to severe
environments).
(b) Certain stem-mounted limit switches on valves.
(c) Containment electrical penetrations, dielectric strength of epoxy resin.
(d) Containment electrical penetrations, fault current protection in relation
to qualified current for the penetration.
(e) Cable employing polyethylene.
We will provide our evaluation of these matters in a future supplement to the
Safety Evaluation Report.
7-7
8.0 ELECTRIC POWER
8.3 Onsite Power
Diesel Generator Operating Status Indication
In Section 8.3.1 of the Safety Evaluation Report, we discussed the diesel genera-
tors, and in Section 8.3.3 of the same report we found them acceptable.
Subsequently, in our review of licensees' reports concerning malfunctions of
diesel generators, we have found that diesel generator status indication available
to the control room operator may be imprecise and could lead to misinterpretation.
The circuits intended to warn the control operator that a diesel generator was not
prepared to respond automatically to an emergency start signal were not doing so
in some circumstances. We requested that the applicant review the diesel genera-
tor alarm circuitry for the Diablo Canyon plant in light of this problem.
The applicant responded in a letter dated December 30, 1977. Six conditions were
identified where the diesel generator would be rendered incapable of responding to
an automatic emergency start signaland where the diesel generator alarmed status
indication would be imprecise. The applicant proposed a design modification for
the addition of one alarm status indication (diesel generator inoperative) for
each diesel generator. This indication will be alarmed for each of the six condi-
tions identified and will be installed prior to operation of the plant. Based on
our-review of the applicant's proposal, we have concluded that the proposed design
modification will eliminate the concern (that the operator's indication might not
warn of an inoperable diesel generator) problem and is in conformance with our
criteria for safety-related display information and is, therefore, acceptable.
We consider this matter resolved.
8-1
9.0 AUXILIARY SYSTEMS
9.5 Air Conditioning, Heating, and Ventilation Systems
9.5.5 Diesel Generator Compartments
In Section 9.5.5 of Supplement No. 6 to the Safety Evaluation Report we described
a modification to the diesel generator compartment ventilation system that the
applicant had informally committed to make. We found the general commitment
acceptable and stated that we would review the details and provide our evaluation
in a future supplement to the Safety Evaluation Report.
The applicant documented the modification in Amendment 58 to the Final Safety
Analysis Report and in a letter dated April 26, 1978. We have reviewed this
information and our evalution is provided below.
In addition to the ventilation features described in the Safety Evaluation Report,
the diesel generators originally drew some cooling air from the main turbine bay
section o.f the turbine building. This air was essential for cooling the generators.
This air for cooling the generators was eliminated when the applicant installed
normally closed fire doors to isolate the diesel generator compartments from the
main section of the turbine building. Ventilation ducts were then installed in
order to draw outside air to the generator and of the compartment and cool the
generator. After cooling the generator this air is drawn through the diesel
radiator and exhausted outside the compartment by the direct engine driven fan.
Since this modification will isolate the diesel generators from a fire in the main
section of the turbine building and it provides adequate ventilation for the
diesel generators, we find it acceptable.
We consider this matter resolved.
9.6 Other Auxiliary Systems
9.6.1 Fire Protection System
In Section 9.6.1 of Supplement No. 4 to the Safety Evaluation Report, we stated
that the fire protection system for Diablo Canyon was acceptable. We also noted
that, when our additional studies of fire protection were completed, we would
require upgrading of the fire protection systems at Diablo Canyon if the results
so dictated.
9-1
Since then we have developed new criteria for fire protection systems and have
begun reviewing fire protection systems according to those criteria (Appendix A to
Branch Technical Position 9.5.1, "Guidelines for Fire Protection for Nuclear Power
Plants Under Review and Construction," August 1976). The applicant submitted a
proposal for compliance with our guidelines in Amendment 51 to the operating
license application, a separate document from the Final Safety Analysis Report.
The applicant is installing numerous modifications to upgrade the plant's fire
protection capabilities including additional fire barriers, sprinkler systems and
alarms. Administrative procedures and training are also being upgraded. We have
reviewed Amendment 51 and subsequent submittals, issued several requests for
additional information and visited the site twice to review the fire protection
provisions. The items that are currently outstanding in this review are listed in
our summary of the site visit on February 14 and 15, 1978.
When our evaluation is completed, we will report the results in a future supplement
to the Safety Evaluation Report. As is currently our policy for operating license
reviews, we will require that, prior to a decision on the issuance of an operating
license, this fire protection review be completed and an acceptable schedule be
established for the installation of any further modifications that may be required
at that time.
9-2
10.0 STEAM AND POWER CONVERSION SYSTEMS
10.4 Other Features
In Supplement No. 1 to the Safety Evaluation Report we presented our evaluation of
the provisions to mitigate the effects of flooding due to a postulated break in the
circulating water system. The applicant's initial measures, which we found
acceptable in Supplement No. 1, are described in the following paragraph.
The flexible joints between the main condenser water boxes and the circulating water
conduits had been fitted with sleeves that would limit the size of a leak from a
flexible joint to less than the capacity of the turbine building drains.
Accordingly, the applicant considered the maximum flooding rate to be one
corresponding to a failure of one condenser water box manhole cover. Assuming no
drainage, such a leak would fill the condenser pits in 10 minutes, during which time
the control room operator would receive alarms. The only safety-related equipment
vulnerable to the flooding would be the diesel generators. The applicant had
installed a door separating the diesel generators from the main turbine building.
The door was arranged to provide a two foot high barrier to water flow but not
interfere with diesel generator cooling air flow. This provided an additional
12 minutes for the operator to take corrective action (stop the circulating water
pumps) assuming no drainage of water from the turbine building. The time available
for corrective action would be less if a larger leak should occur. The door was to
be locked closed and under administrative control during plant operation. When the
door was opened for maintenance, an alarm would be sounded in the control room. We
found these provisions acceptable.
After Supplement No. 1 to the Safety Evaluation Report was issued we became concerned
that the operator might not have sufficient time to take corrective action if a
larger leak should occur. We informally requested that the applicant install an
automatic trip system for the circulating water pumps and the applicant installed
such a system. It initiates a trip of the circulating water pumps upon sensing a
significant water level in the condenser pits. This terminates the circulating
water leak. The system employs two out of three logic and is testable. Since the
system eliminated the need for the operator to take rapid corrective action in the
event of a large leak, we found it acceptable.
Recently, in connection with the fire protection review, the applicant has modified
the door separating the diesel generators from the main turbine building. The new.
door will be a fire barrier blocking the entire passageway. It will also be designed
to prevent water from a circulating water leak from reaching the diesel generators.
10-1
As with the previous door, it will be locked closed and under administrative control
and its opening will be alarmed in the control room. Accordingly, the new door does
not change our previous conclusion that the diesel generators would not be flooded
by a circulating water system leak. Therefore, we find the provisions for protection
against leaks in the circulating water system acceptable.
Since the new door will block the entire passageway, the ventilation system has been
modified to provide generator cooling air from an alternate source. Our evaluation
of the ventilation system is presented in Section 9.5.5 of this supplement where we
find it acceptable.
We consider this matter resolved.
10.5 Auxiliary Feedwater System
In Section 10.5 of the Safety Evaluation Report we discussed the auxiliary feedwater
system. We found the system acceptable.
As discussed in Section 3.2.1 of this supplement, the applicant is qualifying the
raw water storage reservoirs as an extended source of auxiliary feedwater that would
be available to conduct a safe shutdown following the Hosgri event. As part of our
review we will require further information about the provisions to ensure that the
reservoirs would not drain through connected piping that is not qualified. We will
provide our evaluation of this matter in a future supplement to the Safety Evaluation
Report.
10-2
13.0 CONDUCT OF OPERATIONS
13.3 Emergency Planning
In the Safety Evaluation Report we reported that the applicant's emergency
planning program conformed with Appendix E to 10 CFR Part 50, and was acceptable.
The emergency plan submitted by the applicant included California's radiological
emergency plan of the Bureau of Radiological Health of the Department of Public
Health, dated January 1971, and the San Luis Obispo County Sheriff's interim
evacuation plan dated June 1974. The plan also included a letter of agreement
with Sierra Vista Hospital in San Luis Obispo to accept and treat contaminated
patients and a letter of agreement with Swift Aire Lines to furnish aircraft to
transport personnel who may be contaminated.
The applicant submitted Revision 1 to the Emergency Plan on October 12, 1977. In
the revised plan, the Sheriff's plan has been replaced by the San Luis Obispo
County Plan which includes all the elements of the older Sheriff's plan. The
notification procedure remains the same - in an emergency, plant personnel contact
the Sheriff directly, and he relays information to the County Office of Emergency
Services. The California Nuclear Power Plant Emergency Response Plan is now the
July 1975 edition, prepared by the California Office of Emergency Services. The
applicant's written agreement with Swift Aire Lines has been terminated. The
applicant's revised plan states that there is a verbal agreement with Swift Aire,
there is available an applicant company plane for emergency use, and there are
military helicopters available around the clock through local law enforcement
agencies. The applicant's agreement with Sierra Vista Hospital has been
terminated. The revised plan includes a letter of agreement with French Hospital
in which the hospital agrees to accept for treatment injured employees who may be
contaminated with radioactive material. The revised plan also includes a
description of techniques for initial assessment of the amount and type of.radioactivity released into containment in the event of a loss-of-coolant accident.
We reviewed Revision 1 of the Diablo Canyon Emergency Plan and found that it did
not lessen the effectiveness of the previously approved plan, conformed to the
requirements of Appendix E to 10 CFR Part 50, and was acceptable. We provided
testimony to this effect at the public hearing sessions on nonseismic contentions
held in October 1977.
After the public hearing sessions, we performed an additional review of the Diablo
Canyon Emergency Plan in conjunction with the fire protection review. The appli-
cant submitted revisions to the Emergency Plan by letter dated February 8, 1978.
We have reviewed these revisions and concluded that the applicant's emergency
13-1
plans include measures for coping with fire emergencies that conform with the
applicable provisions of Regulatory Guide 1.101, "Emergency Planning for Nuclear
Power Plants." In particular, a satisfactory written agreement is in effect with
the California Department of Forestry which assures the availability of additional
trained personnel and equipment for fire fighting support when called upon. In
addition, the applicant has provided for annual training of these personnel to
assure their familiarity with the plant, access procedures and radiation protection
precautions and has also provided for their participation in an annual drill or
test exercise.
Based on our review, as described above, we have concluded that the Diablo Canyon
Emergency Plan meets the requirements of Appendix E to 10 CFR Part 50 and is
acceptable.
We consider this matter resolved.
13.6 Industrial Security
In Supplement No. 6 to the Safety Evaluation Report, we discussed the Commission's
new security requirements (10 CFR 73.55), the applicant's plans to comply with
those requirements and our review of the applicant's plans. We stated that addi-
tional information would be required before we could complete our review of the
applicant's amended security plan.
The applicant submitted a modified amended security plan (MASP) as Revision 6 to
the plan on July 22, 1977. Subsequent revisions (7, 8 and 9) were submitted with
letters dated January 3, February 2 and March 15, 1978, respectively.
We have reviewed these revisions and visited the site during January 1978 for the
purpose of performing a detailed analysis of the security aspects of safety-related
equipment. In addition, through the use of fault/event diagrams, we performed an
independent study of potential sabotage scenarios to assess the adequacy of
protection being provided for vital equipment.
Based on our review we have found the applicant's security plan provides for a
level of protection consistent with the performance requirements of Section (a) of
10 CFR 73.55 and is, therefore, acceptable.
13-2
18.0 REVIEW BY THE ADVISORY COMMITTEE ON REACTOR SAFEGUARDS (ACRS)
The Advisory Committee on Reactor Safeguards completed a partial review of the
application for operating licenses for Diablo Canyon Units I and 2 on June 5,
1975. A copy of the Committee's June 12, 1975 report on the partial review was
included as Appendix B to Supplement No. 3 to the Safety Evaluation Report. Our
responses to the comments included in that report were provided in Section 18.0 of
Supplement No. 6 to the Safety Evaluation Report.
Since June 1975 the subcommittee has met on May 21, June 25, June 26 and October 11,
1976 and the full Committee has met on November 13, 1976 to consider, primarily,
Diablo Canyon seismic design issues. The Committee did not issue a recommendation
on the seismic design issues. In a memorandum dated December 20, 1976, the Execu-
tive Director of the Advisory Committee on Reactor Safeguards transmitted to the
staff a number of diverse comments made by the Committee's consultants. In a
status report to the Commission, dated June 10, 1977, the Committee stated that it
wished to review the seismic design basis together with the reevaluation since the
subjects were not readily separable. Our review of the applicant's seismic re-
evaluation is provided in Section 3.7 of this supplement and we plan to discuss
these matters further with the Committee.
On August 2, 1977 and August 12, 1977, the subcommittee and the full Committee,
respectively, considered nonseismic aspects of the Diablo Canyon operating license
application. The Committee issued a report on August 19, 1977 dealing with
nonseismic matters. The report is attached as Appendix C to this supplement. Our
responses to the comments included in that report are provided below:
(1) The Committee stated that, "The design of Unit 1 has been modified and
augmented to provide protection against the possible adverse effects of
postulated breaks and cracks in high-energy fluid piping systems outside
containment. The NRC staff has found these systems in compliance with its
current criteria. The Committee concurs. Similar, but not identical, modi-
fications are being made to Unit 2, which differs from Unit 1 in certain
respects. These provisions for Unit 2 have not yet been reviewed by the NRC
staff, but compliance with current criteria will be required. This matter
should be resolved in a manner satisfactory to the NRC staff."
This item has been satisfactorily resolved as discussed in Section 3.6 of
this supplement.
(2) The Committee stated that, "The applicant has proposed several modifications
to his design, administrative procedures, and operator training, to minimize
18-1
the likelihood of an overpressure transient in the reactor coolant system at
temperatures below operating temperatures during startup or shutdown. The
staff has reviewed these modifications and has found them acceptable as an
interim measure. The Applicant is a member of an 'Owner's Group' cooperating
with the reactor vendor in seeking a permanent solution to this generic
problem, and has agreed to implement that solution when it is found
acceptable to the staff. The Committee agrees that the interim measures are
acceptable, and wishes to be informed of the final generic solution."
The status of this matter is currently the same as described in Section 5.2.2
of Supplement No. 6.
For Unit 1, we have accepted the interim measures for use during the first
full cycle. Accordingly, the long term solution for Diablo Canyon Unit 1
must be submitted, reviewed and approved prior to operation of Unit 1
following the first refueling outage.
Since the Unit 2 reactor vessel has somewhat less resistance to brittle
fracture at low temperature than the Unit 1 vessel, we have not yet evaluated
the protection against overpressure transients for Unit 2. Accordingly, this
matter must be acceptably resolved and our evaluation will be provided in a
future supplement to the Safety Evaluation Report prior to a decision on
issuance of an operating license for Unit 2.
We will review the final generic solution and, as the Committee recommended,
we will keep the Committee informed.
(3) The Committee stated that, "At the request of the NRC staff, the applicant
has reevaluated his procedures and systems for the prevention, detection and
suppression of fires as part of a generic review of these features of all
plants operating or under construction. This review has been conducted in
accordance with the provisions of Appendix A to Branch Technical Position
APCSB 9.5-1 as modified by the provisions of Regulatory Guide 1.120 and
Proposed Revision 1 thereto. The applicant has proposed, and has provided a
schedule for implementation of, various modifications to the plant. This
matter should be resolved in a manner satisfactory to the NRC staff."
We are continuing to review the applicant's fire protection provisions and
fire protection system and will provide our evaluation in a future supplement.
As discussed in Section 9.6.1 of this supplement, we will require that the
fire protection review be completed prior to a decision on the issuance of an
operating license.
18-2
(4) The Committee stated that, "The applicant's emergency plans were reviewed
prior to the Committee's letter of June 12, 1975, and found acceptable. A
change in the plans relating to arrangement with a hospital to accept contam-
inated patients has been proposed by the applicant, but has not yet been
reviewed by the staff. This matter should be resolved in a manner satisfac-
tory to the NRC staff."
This item has been satifactorily resolved as discussed in Section 13.3 of
this supplement.
(5) The Committee noted that, "The applicant described the instrumentation avail-
able to monitor the course of an accident. The Committee does not believe
that the instrumentation provided for this purpose meets the full intent of
that proposed in Revision 1 of Regulatory Guide 1.97. The Committee recom-
mends that the provisions of that Guide be implemented by the applicant for
the Diablo Canyon Station in a timely manner once the Regulatory Guide has
been officially promulgated. The Committee wishes to be kept informed."
In Section 7.5 of Supplement No. 1 to the Safety Evaluation Report, we found
the applicant's safety-related display instrumentation, including the
parameters to be monitored during and after the course of an accident, to be
acceptable.
Revision 1 to Regulatory Guide 1.97, "Instrumentation for Light-Water-Cooled
Nuclear Power Plants to Assess Plant Conditions During and Following an
Accident," was issued in August 1977. In light of the Committee's
recommendation and the Diablo Canyon review status we designated Diablo
Canyon as one of the lead plants for implementing Position C.3 of the guide.
We informed the applicant in a letter dated March 10, 1978. We requested
that the applicant describe how this position will be met by June 1, 1978.
Position C.3 of the guide involves four specific types of monitoring: reactor
coolant pressure, containment pressure, radiation level in containment and
radioactivity release rates (through identified release points). Three
operating license applications, including Diablo Canyon, have been selected
as lead plants for implementing this position. The object of this approach
is to learn more about the details of implementing the position on the lead
plants before providing more detailed guidance to all other plants.
The remainder of the guide involves safety analyses to determine what
parameters should be measured to inform the operator about the nature of an
accident and the plant's response. Two construction permit applications have
been selected as lead plants for implementing the entire guide. As before,
the object is to learn more by implementing the guide on the lead plants
before providing more detailed guidance to other plants, including Diablo
Canyon.
18-3
The timing of this review will be in accordance with the generic program
described above, which is documented in our Task Action Plan A-34,
"Instruments for Monitoring Radiation and Process Variables During
Accidents." In accordance with the task action plan we do not require that
the revised Regulatory Guide be implemented for Diablo Canyon, or any other
plant, prior to a decision on issuance of an operating license.
When we receive the applicant's proposal for implementing Position C.3 of the
guide, we will review it and we will keep the Committee informed.
(6) The Committee noted that, "The applicant has modified his Security Plan in
conformance with the requirements of 10 CFR 73.55. The staff has reviewed
this plan and a Security Plan Review Team has visited the plant site. Although
the staff review has not been completed, the applicant has stated that both
the security plan and the physical changes and additions to the plant will be
in accord with the regulations on the effective dates specified therein.
This matter should be resolved in a manner satisfactory to the NRC staff."
This item has been satisfactorily resolved as discussed in Section 13.6 of
this supplement.
(7) The Committee noted that it "has not completed its review of several chiefly
seismic-related matters, including: the seismic design bases and criteria,
the adequacy of the seismic design, the requirements with regard to protec-
tion against tsunamis, the qualification of electrical equipment and instru-
mentation for the postulated accident environment or for seismic effects, and
the acceptability of the design of the reactor pressure vessel supports to
resist forces resulting from a loss-of-coolant accident or from a seismic
event. The Committee will complete its review of these matters following
completion of a review by the NRC staff."
Our evaluation of the seismic design bases and criteria has been completed.
This was described in Sections 2.5 and 3.7 of Supplements 4 and 5.
Our evaluation of the adequacy of the seismic design (seismic reevaluation)
is continuing. A summary of the work done to date is discussed in
Section 1.0 of this supplement. When our evaluation is completed, the
results will be reported in a future supplement.
Our evaluation of protection against tsunamis is completed. This is described
in Section 2.4 of this supplement and Supplement No. 5 to the Safety Evaluation
Report.
18-4
Our evaluation of the qualification of electrical equipment and instrumenta-
tion is continuing. The current status is discussed in Sections 3.10 and 7.8
of this supplement. When our evaluation is completed, the results will be
reported in a future supplement.
Our evaluation of the design of the reactor coolant system supports, includ-
ing the reactor pressure vessel supports, to withstand seismic loads and
loss-of-coolant accident loads is completed and is discussed in Section 3.9
of this supplement.
Our evaluation of a related matter, the design of the reactor fuel to with-
stand these loads, is continuing. The current status is described in
Section 6.3.3 of this supplement. When our evalution is completed, the
results will be described in a future supplement.
We plan to discuss these matters further with the Committee.
(8) The Committee noted that, "With regard to the generic problems cited in the
Committee's report, "Status of Generic Items Relating to Light-Water
Reactors: Report No. 5," dated February 24, 1977, those items considered
relevant to the Diablo Canyon Station are: 11-1, 2, 3, 4, 5, 6, 7, 9; IIA-3,
4, 5, 6, 7; IIB-2; IIC-l, 2, 3, 4, 5; IID-2. These problems should be dealt
with by the Staff and the Applicant as solutions are found."
The status of these items and the other generic items in the Committee's
February 24, 1977 report was discussed in Appendix B, Supplement No. 6 to the
Safety Evaluation Report. An update of this discussion, including reference
to the Committee's most recent report on generic items dated November 15, 1977,
is provided in Appendix B to this supplement. As recommended by the Committee,
we will deal with these generic problems as appropriate solutions are found.
18-5
20.0 FINANCIAL QUALIFICATIONS
In Section 20.0 of the Safety Evaluation Report issued in October 1974, we presented
our evaluation of the applicant's financial qualifications and found them acceptable.
Since several years have elapsed since our review was performed, we will require
additional information from the applicant so that we may update our financial
evaluation. When our review has been completed, we will report the results in a
future supplement to the Safety Evaluation Report.
20-1
22.0 CONCLUSIONS
In Section 22.0 of Supplement No. 6 to the Safety Evaluation Report, we stated
that several items were still outstanding, and that favorable resolution of these
items would be required before a decision on the issuance of operating licenses
for Diablo Canyon Units 1 and 2. Resolutions for some of those items have been
presented in this supplement. Items which currently remain outstanding are
summarized below.
(1) An evaluation of several matters related to qualifying long-term cold shut-
down systems and equipment for a Hosgri 7.5M event (Sections 2.4, 2.5.3,
3.2.1, 7.5 and 10.5 of this supplement).
(2) An evaluation of several matters related to the design of safety-related
structures for a Hosgri 7.5M event (Section 3.8 of this supplement).
(3) An evaluation of several matters related to the design of mechanical systems
and components for a Hosgri 7.5M event (Section 3.9 of this supplement).
(4) An evaluation of several matters related to the seismic qualification ofClass 1E electrical equipment (Section 3.10 of this supplement).
(5) An evaluation of the coolability of the reactor core with combined
loss-of-coolant accident loads and seismic loads (Section 6.3.3 of this
supplement).
(6) An'evaluation of several matters related to environmental qualification of
Class IE electrical equipment (Section 7.8 of this supplement).
(7) An evaluation of the means of protecting the reactor coolant system from
overpressurization transients at low temperature for Unit I in the long-term(after the first fuel cycle) and for Unit 2. However, the evaluation has
been completed for the short-term provisions for Unit I (Section 5.2.2 of
Supplement No. 6).
(8) An evaluation of the vulnerability of the electric power systems and equipment
to a degraded grid voltage condition (Section 8.0 of Supplement No. 6).
(9) An evaluation of a postulated main steam line break inside containment (Section 6.2.1
of Supplement No. 6).
22-1
(10) An evaluation of the plant's fire protection capabilities (Section 9.6.1 of
this supplement).
(11) An evaluation of the normal containment purge system in light of our current
criteria (Section 6.2.3 of this supplement).
(12) An evaluation of proposed changes to the program for control room monitoring
of meteorological parameters (Section 2.3.3 of this supplement).
(13) An evaluation of the proposed seismic scram circuits (Section 7.2 of this
supplement).
(14) An evaluation of measures to reduce the likelihood of a destructive turbine
overspeed event (Section 3.5 of this supplement).
(15) An evaluation of a calculational error in the emergency core cooling
calculations related to metal-water reaction heat release (Section 6.3 of
this supplement).
(16) An evaluation of additional detailed information about reactor vessel
fracture toughness properties (Section 5.2.4 of this supplement).
(17) An update of our evaluation of the applicant's financial qualifications
(Section 20.0 of this supplement).
Subject to favorable resolution of the outstanding matters described above, the
conclusions as stated in Section 22.0 of the Safety Evaluation Report remain
unchanged.
22-2
APPENDIX A
CONTINUATION OF THE CHRONOLOGY OF THE RADIOLOGICAL SAFETY REVIEW
Note: Documents referenced in this chronology (and previous chronologies listed in the
Safety Evaluation Report and Supplement Nos. 1-6) are available for public inspec-
tion at the NRC Public Document Room, 1717 H Street, N.W., Washington, DC, 20555,
and at the Local Public Document Room for the Diablo Canyon Nuclear Power Station
located at the San Luis Obispo County Free Library, P. 0. Box X, San Luis Obispo,
California, 93406.
September 10, 1976
February 2, 1977
June 25,1977
July 14, 1977
July 18, 1977
July 22, 1977
July 26, 1977
July 27, 1977
August 2, 1977
August 12, 1977
Supplement No. 5 to the Safety Evaluation Report.
Report from NRC staff consultant (Dr. Newmark) entitled, "Notes on
Approximate Relations for Sensitivity of Design Spectra to Varia-
tions in Damping Factor and Ground Acceleration."
Preliminary working draft report on seismic risk assessment from
staff consultants (Dr. Newmark and Dr. Ang).
Supplement No. 6 to Safety Evaluation Report.
Letter to applicant providing staff comments on proposed seismic
design criteria - tanks, piping and equipment.
Letter from applicant transmitting revised security plan and
attachment (enclosure withheld from public disclosure).
Letter from applicant transmitting Annual Financial Report for
1976.
Submittal of Amendment 51 consisting of information on fire
protection rereview.
ACRS Subcommittee meeting to discuss nonseismic aspects of operating
license application.
ACRS Full Committee meeting to discuss nonseismic aspects of
operating license application.
A-i
August 15-17, 1977
August 19, 1977
August 24, 1977
August 24, 1977
August 25, 1977
August 25, 1977
August 29, 1977
August 30, 1977
September 1, 1977
September 8, 1977
September 15, 1977
September 21, 1977
September 26, 1977
September 29, 1977
Site visit to discuss fire protection.
ACRS letter providing recommendation to the Commission on nonseismic
aspects of operating license application.
Letter to applicant requesting information about the seismic
reevaluation (questions on Amendment 50 in the structural engi-
neering area).
Letter to applicant requesting information about Unit 1 containment
structural integrity test.
Motion from PG&E to Licensing Board requesting interim operating
license.
Amendment 52 to the application providing seismic risk assessment
in support of interim operating license.
Letter to applicant transmitting staff guidance entitled, "Nuclear.
Plant Fire Protection Functional Responsibilities, Administrative
Controls and Quality Assurance."
Letter to applicant requesting information about (1) environmental
qualification of electrical equipment, (2) submerged equipment
inside containment, and (3) pipe breaks outside containment for
Unit 2.
Letter to applicant requesting information about security plan
(attachment withheld from public disclosure).
Site visit to discuss interim operating license review (practicality
of future modifications).
Letter from applicant providing information about main steam line
break inside containment requested June 1, 1977.
Letter to applicant requesting additional information concerning
need for power in regard to an interim operating license.
Letter from applicant providing information about need for power
requested September 21, 1977.
Submittal of Amendment 53 including miscellaneous changes to
Amendment 50.
A-2
September 29, 1977
September 30, 1977
October 3, 1977
October 3, 1977
October 4, 1977
October 6, 1977
October 10, 1977
October 10, 1977
October 10, 1977
October 12, 1977
October 12, 1977
October 12, 1977
Letter from applicant transmitting report in support of interim
operating license entitled, "Analysis of Relative Risk Associated
with Operation of the Diablo Canyon Nuclear Power Plant, Unit 1,
for an Interim Licensing Period."
Meeting with California Energy Commission and applicant to discuss
interim operating license review (need for power).
Letter from applicant providing part of the information requested
August 30, 1977 (information about (1) environmental qualification
of equipment, and (2) submerged equipment inside containment).
Letter from applicant providing information about degraded grid
voltage requested June 6, 1977.
Letter from applicant concerning practicality of future modifica-
tions in support of interim operating license.
Meeting with applicant to discuss interim operating license review
(seismic risk assessment).
Letter from applicant providing information about proposed
inservice inspection program to comply with 10 CFR 50.55a(g)
requested May 23, 1977.
Letter from applicant transmitting report LL-41 entitled,
"Probabilities of Peak Accelerations Based on the Geologic Record
of Fault Dislocation."
Letter from applicant providing remainder of information requested
August 30, 1977 (information about pipe breaks outside containment
for Unit 2).
Letter from applicant transmitting Revision I to the Emergency
Plan.
Letter from applicant transmitting report LL-43 entitled,
"Discussion of Attenuation Equations" in support of interim
operating license.
Letter from applicant providing information about need for power
requested at meeting on September 26, 1977 (in support of interim
operating license).
A-3
October 14, 1977
October 14, 1977
October 14, 1977
October 17-18, 1977
October 18, 1977
October 20-21, 1977
October 21, 1977
October 25, 1977
October 27, 1977
October 28, 1977
November 2, 1977
November 2, 1977
November 3, 1977
November 7, 1977
Submittal of Amendment 54 including information on earthquake
probabilities related to (1) geologic record of fault displacements,
and (2) attenuation equations.
Letter from applicant providing information about seismic risk
assessment (Amendment 52) requested at meeting October 6, 1977.
Letter to applicant concerning schedule for review of interim
operating license request.
Public hearings concerning nonseismic safety issues.
Letter from applicant describing proposed change to meteorological
data to be displayed in the control room.
Meeting with applicant to discuss seismic reevaluation (PG&E
responses to staff questions on Amendment 50 in mechanical engi-
neering area).
Letter from applicant transmitting Appendix B to report LL-41
entitled, "Probabilities of Peak Site Acceleration Based on the
Geologic Record of Fault Dislocation."
Letter to applicant providing staff guidance on physical security
assessment models under 10 CFR 73.55(a).
Letter from California Energy Commission about need for power in
relation to interim operating license.
Submittal of Amendment No. 55 including information about (1)
environmental qualification of electrical equipment, and (2)
miscellaneous changes.
Letter from applicant providing part of information on structural
engineering aspects of Amendment 50 requested August 24, 1977.
Letter from applicant concerning the California Energy Commission's
assessment of need for power in relation to interim operating license.
Meeting with applicant to discuss status of operating license
reviews (interim and full-term).
Report from NRC staff consultants (Dr. Newmark and Dr. Ang) entitled,
"A Probabilistic Seismic Safety Assessment of the Diablo Canyon
Nuclear Power Plant."
A-4
November 9, 1977
November 9, 1977
November 10, 1977
November 10, 1977
November 10, 1977
November 10, 1977
November 10, 1977
November 11, 1977
November 15, 1977
November 15, 1977
November 17, 1977
November 22, 1977
November 22, 1977
November 22, 1977
Letter to applicant requesting information about quality assurance
provisions for fire protection.
Letter to applicant requesting information about diesel generator
status indication.
Letter to applicant requesting information about seismic reevalua-
tion (Amendment 50 to the application).
Letter to applicant providing staff guidance concerning industrial
security devices.
Meeting with applicant to discuss fire protection.
Letter to applicant requesting additional information concerning
interim operating license in the following areas: (1) relative
risk; (2) earthquake probabilities; (3) asymmetric loads; and (4)
long-term cooling.
Meeting with applicant to discuss seismic reevaluation - reactor
coolant system fracture mechanics analysis.
Meeting with applicant to discuss seismic reevaluation - combined
load analysis of reactor coolant system.
Letter from applicant providing part of information about seismic
reevaluation (Amendment 50) requested November 10, 1977.
Submittal of Amendment 56 including (1) additional material on
seismic reevaluation revising Amendment 50, and (2) fracture
mechanics study of reactor coolant system.
Letter to applicant requesting decision on whether or not the
interim operating license request will continue to be pursued.
Meeting with applicant to discuss seismic reevaluation (systems
required for safe shutdown).
Letter to applicant requesting information about seismic reevalua-
tion (combined loads outside reactor coolant system).
Letter to applicant providing staff position on degraded grid
voltage.
A-5
November 23, 1977
December 1, 1977
December 1, 1977
December 5, 1977
December 6, 1977
December 9, 1977
December 12, 1977
December 15, 1977
December 16, 1977
December 20, 1977
December 21, 1977
December 21, 1977
December 23, 1977
Letter to applicant requesting information about reactQr vessel
fracture toughness properties.
Letter from applicant providing part of information about seismic
reevaluation (Amendment 50) requested August 24, 1977.
Letter from applicant providing information about Unit 1 structural
integrity test requested August 24, 1977.
Letter from applicant providing additional information about
qualification of electrical equipment (temperature monitoring and
recording system).
Meeting with applicant to discuss methods of expediting operating
license review.
Letter to applicant requesting information about fire protection
review.
Letter to applicant requesting information about seismic reevalua-
tion (systems for safe shutdown).
Meeting with applicant to discuss schedule for review of operating
license application.
Letter from applicant requesting extension of construction
completion dates for Units 1 and 2.
Letter from applicant providing remaining information on structural
engineering aspects of Amendment 50 requested August 24, 1977.
Letter from applicant providing information about seismic
requalification of electrical equipment informally requested by
staff.
Letter from applicant providing part of information about interim
operating license requested November 10, 1977 (information about
relative risk).
Letter from applicant providing part of information about interim
operating license requested November 10, 1977 (information about
earthquake probabilities).
A-6
December 27, 1977
December 27, 1977
December 27, 1977
December 30, 1977
January 3, 1978
January 3, 1978
January 4-11, 1978
January 5, 1978
January 5-6, 1978
January 10-13, 1978
January 12, 1978
January 12-13, 1978
January 14, 1978
January 16-20, 1978
January 17, 1978
Letter to applicant requesting information about fire protection.
Letter to applicant providing staff evaluation of proposed changes
to meteorological data (applicant letter of October 18, 1977).
Letter to applicant requesting information about seismic reevalua-
tion (damping values).
Letter from applicant providing information about diesel generator
status indication requested November 9, 1977.
Letter from applicant transmitting revised Diablo Canyon Security
Plan (enclosure withheld from public disclosure).
Request from intervenors to the Commissioners to stop seismic
modifications pending completion of staff review. Matter was
referred to staff to be treated as request for show cause order.
Site visit to discuss industrial security provisions with applicant.
Letter from applicant transmitting document entitled, "Plate
Boundary and Diffused Areal Probabilistic Considerations and
Revised Figure 45A-2."
Meetings with applicant to discuss reactor coolant system analysis
(asymmetric loads, vessel supports, reactor cavity pressure calcula-
tions, subcompartment pressure loads, analytical models for reactor
coolant system).
Site visit to.discuss industrial security.
Letter from applicant providing information about seismicrequalification of equipment including testing in place.
Meeting with applicant to discuss fire protection.
Site visit to tour plant in connection with seismic design Meetings.
Meetings with applicant - seismic design criteria implementation-
review meetings (audits) in the structural engineering area.
Letter from applicant providing information'about seismic reevalua-
tion requested November 22, 1977 (combined loads outside the
reactor coolant system).
A-7
January 17, 1978
January 19, 1978
January 20, 1978
January 23, 1978
January 23, 1978
January 23-27, 1978
January 24, 1978
January 24, 1978
January 25,1978
January 26, 1978
January 30, 1978
January 30, 1978
January 30, 1978
Letter from applicant providing information about seismic reevalua-
tion requested December 27, 1977 (damping values).
Letter from applicant providing information about qualification of
containment fan coolers requested informally by staff.
Letter from Westinghouse providing analysis of reactor coolant
system for asymmetric loads.
Submittal of Amendment 57 including meteorology information
discussed in letters of October 18, 1977 and December 27, 1977.
Letter to applicant indicating the staff would proceed on a high
priority basis to complete review of full-term operating license
but, with respect to interim operating license, would only continue
reviewing the probability studies.
Meetings with applicant - seismic design criteria implementation
review meetings (audits) in the mechanical engineering area for
PG&E's scope of work.
Letter from applicant transmitting reply to staff position on
degraded grid voltage conditions sent November 22, 1977.
Letter from applicant transmitting report entitled, "Stress Evalua-
tion of Piping Systems Assuming Single Snubber Failures" (part of
information requested November 10, 1977 concerning seismic design
reevaluation).
Letter to applicant providing staff guidance on overpressure
transient protection for the long term.
Letter from applicant providing information requested December 12,
1977 about seismic design reevaluation (systems required for safe
shutdown).
Letter to applicant requesting information about the security plan
(enclosure withheld from public disclosure).
Letter to applicant requesting information about fire protection.
Letter to applicant requesting information about (1) inservice
inspection, and (2) emergency planning for fire protection.
A-8
January 31, 1978 toFebruary 2, 1978
February 1, 1978
February 1, 1978
February 2, 1978
February 2, 1978
February 2, 1978
February 6, 1978
February 8, 1978
February 8, 1978
February 9, 1978
February 10, 1978
February 14, 1978
Meetings with applicant - seismic design criteria implementation
review meetings in the mechanical engineering area for the
Westinghouse scope of work.
Letter to applicant providing staff guidance on inservice inspec-
tion program under 10 CFR 50.55a(g).
Extended Construction Permits for Unit 1 from January 1, 1977 to
September 30, 1978 and for Unit 2 from July 31, 1977 to December 31,
1978 (published February 8, 1978, 43 FR 5446).
Letter from applicant providing expanded and additional responses
to staff request for information of August 24, 1977 (structural
engineering aspects of Amendment 50).
Letter from applicant transmitting revisions to Diablo Canyon
security plan in response to staff request of January 30, 1978
(enclosure withheld from public disclosure).
Letter to applicant providing staff evaluation of tornado protection.
Letter from applicant providing information about fire protection
requested November 9, December 9, December 27, 1977 and January 30, 1978.
Letter from applicant providing part of information requested
January 30, 1978 (information about emergency planning for fire
protection).
Letter from applicant to Licensing Board indicating status of
request for an interim operating license. Letter indicated that,
although staff was no longer reviewing the matter, except for the
probability studies, PG&E did not wish to withdraw the application
because it might wish to reactivate it in the future if the full-term
license review were delayed for some unforeseen reason.
Meeting with applicant to follow up seismic design audit in
structural engineering area (January 23-27, 1978).
Letter from applicant providing information about qualification of
containment fan coolers requested informally by the staff.
Letter from applicant providing (1) part of information about
seismic design reevaluation requested November 10, 1977 (mathe-
matical model of reactor internals), and (2) information about
A-9
February 14-15, 1978
February 15, 1978
February 15, 1978
February 16, 1978
February 21, 1978
February 22, 1978
February 28, 1978 toMarch 1, 1978
February 28, 1978
February 28, 1978
March 14, 1978
March 15, 1978
March 20, 1978
March 22, 1978
subcompartment pipe breaks in containment requested informally at
the me4ting of January 5, 1978.
Site visit to discuss fire protection.
Letter from applicant providing information about qualification
testing of submerged equipment in containment informally requested
by staff.
Letter from applicant providing report entitled, "Data Sets and
Their Treatment in Obtaining Attenuation Relationships," regarding
earthquake probabilities.
Meeting with applicant to follow up seismic design audit in
structural engineering area (January 23-27, 1978).
Letter from applicant providing description of seismic scram device
to be installed.
Letter from applicant providing report on reactor coolant systems
response to combined loads (LOCA plus seismic).
Meeting with applicant to follow up seismic design audit in
structural engineering area (January 23-27, 1978).
Submittal of Amendment 58 consisting of miscellaneous changes to
the FSAR.
Submittal of Amendment 59 consisting of additional material on
seismic reevaluation revising Amendment 50. This documented
material that had been previously submitted by letter, some of it
in changed form.
Meeting with applicant to discuss fire protection.
Letter from applicant providing revisions to security plan
(enclosure withheld from public disclosure).
Letter from applicant revising submittal of January 24, 1978 on
degraded grid voltage.
NRC staff denied intervenor's request for show cause order on
halting seismic modifications (January 3, 1978).
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March 27, 1978
March 28, 1978
March 28, 1978
April 5, 1978
April 11, 1978
April 11, 1978
April 11, 1978
April 11, 1978
April 12, 1978
April 17, 1978
April 17, 1978
April 19, 1978
Letter from applicant providing information on assumed pipe snubberfailures supplementing report submitted January 24, 1978.
Submittal of Amendment 60 consisting of revisions to seismicreevaluation (Amendment 50) including material that had been
submitted previously by letter, some of it in changed form.
Submittal of Amendment 61 consisting of (1) additional information
on meteorology display methods requested informally by the staff,and (2) information about reactor vessel toughness properties
requested November 23, 1977.
Letter from applicant supplementing submittal of January 24, 1978
on pipe snubber failures (information on steam generator snubbers).
Meeting with applicant to discuss analysis of reactor fuel undercombined earthquake and LOCA loads.
Letter from applicant providing justification for operating basis
earthquake.
Letter from applicant providing information related to turbine
missile probability studies.
Letter from applicant supplementing letter of February 22, 1978 onreactor coolant system response to combined loads (support key
material properties).
Letter from applicant supplementing previous submittals on piping
system analyses (October 20-21, 1977 meeting, letter November 15,
1977, Amendment 59).
Letter from applicant supplementing letter of February 24, 1978 on
seismic scram.
Letter from applicant providing further information on systems forsafe shutdown (hose connections).
Letter to applicant providing revised intrusion detection systems
handbook.
A-11
APPENDIX B
'CONTINUATION OF DISCUSSION
ADVISORY COMMITTEE ON REACTOR SAFEGUARDS GENERIC ITEMS
The Advisory Committee on Reactor Safeguards (Committee) periodically issues a
report listing various generic matters applicable to large light-water reactors.
In addition, the NRC staff periodically reports on the status of its efforts to
resolve these generic items.
These are items which the Committee and the NRC staff, while finding present plant
designs acceptable, believe have potential for adding to overall safety margins
and so should be considered for application to the extent reasonable and practi-
cable as solutions are found, recognizing that such solutions may occur after
completion of a specific plant. This is consistent with our continuing efforts to
reduce the already small safety risk from nuclear power plants.
In Appendix B to Supplement No. 6 to the Safety Evaluation Report, we described
the status of each of these generic items as it related to Diablo Canyon. In the
descriptions reference was made to the latest reports then available - the staff
status report of January 31, 1977 and the Committee's report of February 24, 1977.
More recent reports are now available. A staff status report was issued on
October 25, 1977 and the latest Committee report was issued on November 15, 1977.
Where significant changes have occurred in the status of these generic items in
relation to Diablo Canyon since Supplement No. 6 was issued, including changes due
to issuance of the new reports, the new status is described below. The numbering
corresponds to that in Supplement No. 6. In all other cases, the status remains
essentially the same as was described in Supplement No. 6.
Group II - Resolution Pending
(1) Turbine Missiles
In addition to the generic program discussed in Supplement No. 6, we have
performed a specific review of this matter for Diablo Canyon. Our evaluation
is described in Section 3.5 of this supplement.
B-1
(5) Monitoring for Excessive Vibration or Loose Parts Inside the Pressure Vessel
The Committee has now divided this item into two parts - monitoring for loose
parts and monitoring for vibration.
With regard to monitoring for loose parts, the status remains the same as
described in Supplement No. 6. Diablo Canyon employs a loose parts monitor-
ing system. The generic review is continuing and will establish criteria for
such systems as indicated in our status reports dated January 31, 1977 and
October 25, 1977.
With regard to monitoring for vibration, a different type of instrument may
be indicated. Accordingly, this may amount to a new item that was not
addressed in our status report dated October 25, 1977. This generic matter
will be discussed in a future staff status report.
(9) The Advisability of a Seismic Scram
Supplement No. 6 indicated that the advisability of such a device for Diablo
Canyon was still being discussed with the Committee although the staff
considered the generic studies completed and did not plan to require a
seismic scram.
Since then, the applicant has decided to install a seismic scram device at
Diablo Canyon (Section 7.2 of this supplement).
Further, some additional generic review is now underway as discussed in our
status report dated October 25, 1977.
Group IIA - Resolution Pending - Items Added Since December 18, 1972
(3) Rupture of High Pressure Lines Outside Containment
Supplement No. 6 indicated that we expected this item to be acceptably
resolved for Diablo Canyon by employment of our current criteria in the
review, which was not yet completed. Our review is now completed and the
design meets our current criteria (Section 3.6 of this supplement).
In addition, Supplement No. 6 indicated that the staff considered the generic
item to be acceptably resolved. In its latest report, dated November 15,
1977, the Committee also considered the generic item to be resolved.
B-2
(5) Isolation of Low Pressure System from High Pressure System
As discussed in Supplement No. 6, we consider this item resolved for Diablo
Canyon by employment of acceptable design measures.
In addition, Supplement No. 6 indicated that the staff considered the generic
item acceptably resolved. In its latest report, dated November 15, 1977, the
Committee also considered the generic item resolved.
Group IIC - Resolution Pending - Items Added Since March 12, 1975
(2) Design Features to Control Sabotage
Supplement No. 6 indicated that we expected this item to be resolved by
employing our current criteria in the review, which was not yet completed.
The review is now completed and the protection meets our current criteria
(Section 13.6 of this supplement).
In addition, the generic review is continuing as was indicated in Supplement
No. 6.
(4) Vessel Support Structures
As indicated in Supplement No. 6, our generic review is continuing.
The status of the Diablo Canyon analyses is now different than was described
in Supplement No. 6. We have completed our evaluation of the reactor coolant
system support structures, including the reactor vessel supports (Section 3.9
of this supplement). Our evaluation of a related matter, the design of the
reactor fuel assemblies, is continuing. We will require resolution of this
matter prior to licensing and will report the resolution in a future supple-
ment (Section 6.3.3 of this supplement).
Group IE - Resolution Pending - Items Added Since February 24, 1977
(1) Soil - Structure Interactions
Regarding the traditional controversy about soil structure interaction, we
consider this matter resolved for Diablo Canyon by employment of acceptable
analysis procedures that involved placing the design input motions directly
onto the base slabs of structures rather than utilizing soil structure
interaction analyses. Soil structure interaction analyses were performed for
the buried diesel fuel oil tanks, where they are approriate. (Section 3.8 of
this supplement).
B-3
In a somewhat related matter, we have allowed some reduction of the high
frequency portion of ground response spectra to account for building size
effects in relation to ground motion waves. We have also, however, required
consideration of the torsion that can be expected to result from ground
motion waves. We consider these design techniques acceptable (Section 3.7
of Supplement No. 5 to the Safety Evaluation Report and Section 3.8 of this
supplement).
This is a new item that was not discussed in our status report dated
October 25, 1977. This generic matter will be discussed in a future staff
status report.
B-4
APPENDIX CUNITED STATES
NUCLEAR REGULATORY COMMISSIONADVISORY COMMITTEE ON REACTOR SAFEGUARDS
WASHINGTON. 0. C. 20555
August 19, 1977
Honorable Joseph M. HendrieChairmanU. S. Nuclear Regulatory CommissionWashington, DC 20555
Subject: REPOIC ON FURdMER PARIAL REVIEW OF DIABLO CANYON NUCLEAR
POWER STATION UNITS 1 AND 2
Dear Dr. Hendrie:
During its 208th meeting, August 11-13, 1977, the Advisory Committeeon Reactor Safeguards continued its review of the application of thePacific Gas and Electric Company for authorization to operate theDiablo Canyon Nuclear Power Station Units 1 and 2. The Committee re-ported previously on this application in its letter of June 12, 1975.Since that time, several meetings of a Subcommittee and of the fullCommittee have been held to review and discuss questions relating tothe seismic design bases and criteria, and a Subcommittee meeting washeld in Des Plaines, Illinois on August 2, 1977 to review safety mattersnot related to seismic concerns. This report is related only .to thosenonseismic matters. During its review, the Committee had the benefitof discussions with representatives and consultants of the Pacific Gasand Electric Company, the Westinghouse Electric Corporation, the NuclearRegulatory Conmission Staff, .and a consultant to intervenors in thepublic hearings before an NRC Atomic Safety and Licensing Board. TheCommittee also had the benefit of the documents listed.
The original emergency core cooling system performance analyses had beenmade using an initial upper head temperature corresponding to the coreinlet temperature. These analyses have been redone using an upper headtemperature corresponding to that in the hot leg. Calculations usingthe latest Westinghouse evaluation model (October 1975 revision) showccmpliance with the criteria of 10 CFR 50.46 with a peaking factor of 2.32.
In its letter of June 12, 1975, the Committee noted that the Diablo Canyonunits were expected to be among the first reactors of this type to operateat a power as high as 3411 MWt and with a full core of the 17x17 fuelassembies, and noted further that an augmented start-up program and a morecautious than normal approach to full power would be desirable for suchplants. In the interim, the recommended augmented start-up program hasbeen employed for the Trojan and Beaver Valley reactors, which are inthe categories described above. In view of this experience, and subject
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Honorable Joseph M. Hendrie - 2 - August 19, 1977
to completion of the Staff's review of the reports on these start-up pro-grams, the Committee does not believe it will be necessary to imposespecial restrictions on the start-up and power escalation programs forthe Diablo Canyon units beyond those normally considered prudent by theNRC Staff.
The design of Unit 1 has been modified and augmented to provide protectionagainst the possible adverse effects of postulated breaks and cracks inhigh-energy fluid piping systems outside containment. The NRC Staffhas found these systems in compliance with its current criteria. The Com-mittee concurs. Similar but not identical modifications are being made toUnit 2, which differs from Unit I in certain respects. These provisionsfor Unit 2 have not yet been reviewed by the NRC Staff, but compliance withcurrent criteria will be required. This matter should be resolved in amanner satisfactory to the NRC Staff.
The Applicant has proposed several modifications to his design, adminis-trative procedures, and operator training, to minimize the likelihood ofan overpressure transient in the reactor coolant system at temperaturesbelow operating temperatures during startup or shutdown. The Staff hasreviewed these modifications and has found them acceptable as an interimmeasure. The Applicant is a member of an "Owner's Group" cooperating withthe reactor vendor in seeking a permanent solution to this generic problem,and has agreed to implement that solution when it is found acceptable tothe Staff. The Committee agrees that the interim measures are acceptable,and wishes to be informed of the final generic solution.
At the request of the NRC Staff, the Applicant has reevaluated his pro-cedures and systems for the prevention, detection and suppression of firesas part of a generic review of these features of all plants operating orunder construction. This review has been conducted in accordance with theprovisions of Appendix A to Branch Technical Position APCSB 9.5-1 as mod-ified by the provisions of Regulatory Guide 1.120 and Proposed Revision 1thereto. The Applicant has proposed, and has provided a schedule for im-plementation of, various modifications to the plant. This matter should beresolved in a manner satisfactory to the NIC Staff.
The Applicant's emergency plans were reviewed prior to the Committee'sletter of June 12, 1975 and found acceptable. A change in the plansrelating to arrangements with a hospital to accept contaminated patientshas been proposed by the Applicant, but has not yet been reviewed by theStaff. This matter should be resolved in a manner satisfactory to theNX Staff.
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Honorable Joseph M. Hendrie -3 - August 19, 1977
The Applicant described the instrumentation available to monitor thecourse of an accident. The Committee does not believe that the instru-mentation provided for this purpose meets the full intent of that pro-posed in Revision 1 of Regulatory Guide 1.97. The Committee recommendsthat the provisions of that Guide be implemented by the Applicant for theDiablo Canyon Station in a timely manner once the Regulatory Guide hasbeen officially pramulgated. The Committee wishes to be kept informed.
The Applicant has modified his Security Plan in conformance with the re-quirements of 10 CFR 73.55. The Staff has reviewed this plan and aSecurity Plan Review Team has visited the plant site. Although the Staffreview has not been completed, the Applicant has stated that both thesecurity plan and the physical changes and additions to the plant will bein accord with the regulations on the effective dates specified therein.This matter should be resolved in a manner satisfactory to the NRC Staff.
In both written reports and in oral presentations to the ACRS a consultantto intervenors in the public hearings before an NRC Atomic Safety andLicensing Board has alleged serious deficiencies in the Applicant's QualityAssurance programs for design, construction, and operation. These alle-gations have been reviewed by the NRC Staff, and their findings reportedto the Committee. The Staff has found no deficiencies in these programsof a nature serious enough to affect the safe operation of the plant.The Committee concurs.
The Committee has not completed its review of several chiefly seismic-related matters, including: the seismic design bases and criteria, theadequacy of the seismic design, the requirements with regard to protectionagainst tsunamis, the qualification of electrical equipment and instru-mentation for the postulated accident environment or for seismic effects,and the acceptability of the design of the reactor pressure vessel supportsto resist forces resulting from a loss-of-coolant accident or from a seismicevent. The Committee will complete its review of these matters followingcompletion of a review by the NFC Staff.
With regard to the generic problems cited in the Committee's report, "Statusof Generic Items Relating to Light-Water Reactors: Report No. 5," datedFebruary 24, 1977, those items considered relevant to the Diablo CanyonStation are: 11-1, 2, 3, 4, 5, 6, 7, 9; IIA-3, 4, 5, 6, 7; IIB-2; IIC-l,2, 3, 4, 5; IID-2. These problems should be dealt with by the Staff andthe Applicant as solutions are found.
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*
Honorable Joseph M. Hendrie - 4 - August 19, 1977
Except for those matters identified above as requiring further Comnitteereview, the ACRS believes that, if due consideration is given to the fore-.going, and subject to satisfactory completion of construction and pre-operational testing, there is reasonable assurance that the Diablo CanyonNuclear Power Station Units 1 and 2 can be operated at power levels up to3338 and 3411 MW(t), respectively, without undue risk to the health andsafety of the public.
The Committee will report in the future on those matters for which itsreview has not yet been completed.
Sincerely ? s,
M. Bender
Chairman
References
1. Final Safety Analysis Report (FSAR) for the Diablo Canyon NuclearPower Station, Units 1 and 2, and Amendments 1-51 to the FSAR.
2. Safety Evaluation Report dated October 16, 1974, and Supplements1-6 dated January 31, 1975, May 9, 1975, September 18, 1975, May 1976,September 1976, and July 1977.
3. Documents provided to the Coumiittee by Richard B. Hubbard, TechnicalConsultant to Intervenors in the Public Hearings Before an NRC AtomicSafety and Licensing Board.
a. Diablo Canyon Nuclear Power Plant, Units No. 1 and 2,Atomic Safety and Licensing Board (ASLB), Affidavit ofRichard B. Hubbard, March 10, 1977.
b. Diablo Canyon Nuclear Power Plant, Units No. 1 and 2,ASLB, Supplemental Affidavit of Richard B. Hubbard,April 27, 1977.
c. Written Statement dated June 23, 1977 from Richard B. Hubbard.to ACRS Subcommittee on Diablo Canyon concerning, SeismicRisk Uncertainty Deficiencies in Diablo Canyon QA Programand its Implementation.
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Honorable Joseph M. Hendrie - 5 - August 19, 1977
d. Written Statement dated June 30, 1977 from Richard B. Hubbardto Subcommittee on Energy and the Environment, Committeeon Interior and Insular Affairs, United States House ofRepresentatives, Washington, D.C. concerning Effectivenessof NFC Regulations - Modifications to Diablo Canyon NuclearUnits.
e. Written Statement dated August 2, 1977 from Richard B.Hubbard to ACRS Subcommittee on Diablo Canyon concerning.Risk Uncertainty Due to Flaws in Diablo Canyon QA Programand Failure to Implement Current NRC Practices.
f. Written Statement dated August 12, 1977 from Richard B. Hubbardto the ACRS on Diablo Canyon concerning Risk Uncertainty Due toDeficiencies in Diablo Canyon Quality Assurance Program andFailure to Implement Current NRC Practices.
4. NBC Staff Report received August 2, 1977 by ACRS Subcommittee onDiablo Canyon concerning first four statements by Richard B. Hubbard.
5. Pacific Gas and Electric Company letters to the NRC as follows:
a. Prevention of Primary System Overpressurization, July 5, 1977.
b. ECCS Analysis, June 10, 1977.
c. ATWS, September 30, 1976.
d. Reactor Vessel Support Structure, January 13, 1976.
e. Pipe Breaks Outside of Containment, January 14, 1976.
6. Diablo Canyon Power Plant Physical Security Plan, Rev. 6, July 22,1977 (Company Confidential to be withheld from public disclosurein accordance with 10 CFR 2.790).
C-5
APPENDIX D
BIBLIOGRAPHY
(Documents referenced in or used to prepare Supplement No. 7 to the Safety Evalua-
tion Report for the Diablo Canyon Nuclear Power Station, Units 1 and 2, are listed
below. This list of documents is in addition to those previously listed in the
bibliographies for the Safety Evaluation Report and Supplement Nos. 1, 4 and 5 to
the Safety Evaluation Report.)
Slope Stability
1. Newmark, Nathan M., "Effect of Earthquakes on Dams and Embankments," paper
presented at the Fifth Rankine Lecture, Institution of Civil Engineers,
London, England, February 1965.
2. Seed, H. Bolton and Goodman, R. E., "Earthquake-Induced Displacements in Sand
Embankments," Journal of the Soil Mechanics and Foundations Division, ASCE,
Vol. 92, No. SM2, March 1966.
3. Page, R. A., D. M. Boore, W. B. Joyner and H. W. Coulter (1972), Ground
motion values for use in the seismic design of the Trans-Alaska Pipeline
System: U.S. Geological Survey Circular 672.
Seismology
4. Ang, A. H-S and N. M. Newmark, 1977, "A Probabilistic Seismic Safety Assessment
of the Diablo Canyon Nuclear Power Plant," Report to the NRC, N. M. Newmark
Consulting Engineering Services.
Seismic Reevaluation
5. NRC staff report to the Advisory Committee on Reactor Safeguards for considera-
tion at the Committee's meeting on November 13, 1976. Documented in NRC
staff files and Public Document Rooms as a memorandum from Dennis Allison to
John Stolz dated November 24, 1976, Subject: Seismic Reevaluation of the
Diablo Canyon Nuclear Power Plant.
6. "Seismic Analysis of Structures and Equipment for Nuclear Power Plants,"
BC-TOP-4A (Rev. 3, November 1974), Topical Report, Bechtel Power Corporation,
San Francisco, California.
D-1
7. "Dynamics of Fixed-Base Liquid-Storage Tanks", Veletsos, A. S. and
Yang, J. Y., Proceedings of U.S. - Japan Seminar on Earthquake Engineering
Research with Emphasis on Lifeline Systems, 1976.
8. Atomic Energy Commission Publication TID 7024, "Nuclear Reactors and
Earthquakes, August 1963, Washington, D.C.
9. "Problems in Wave Propagation in Soil and Rock", Newmark, N. M.,. Symposium
Wave Propagation and Dynamic Properties of Earth Materials, 1968.
lD. Newmark, N.M., "Notes on Approximate Relations for Sensitivity to Variations
in Damping Factor and Ground Acceleration," A Memorandum to the Nuclear
Regulatory Commission, February 2, 1977.
D-2
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